Method for predicting the occurrence of metastasis in breast cancer patients

ABSTRACT

The present invention relates to the prognosis of the progression of breast cancer in a patient, and more particularly to the prediction of the occurrence of metastasis in one or more tissue or organ of patients affected with a breast cancer.

FIELD OF THE INVENTION

The present invention relates to the prognosis of the progression of breast cancer in a patient, and more particularly to the prediction of the occurrence of metastasis in one or more tissue or organ of patients affected with a breast cancer.

BACKGROUND OF THE INVENTION

Breast cancer is the most common malignant disease in Western women. It is not the primary tumour, but the occurrence of metastases in distant organs that is the major cause of death for cancer patients. Once solid secondary tumours are established, the chances of long-term survival fall from 90% to around 5%. Despite the progress in the development of targeted therapies, approximately 40% of the treated patients relapse and ultimately die of metastatic breast cancer. A better understanding of the molecular and cellular mechanisms underlying metastasis might improve the development of effective therapies that would ameliorate breast cancer care.

Malignant breast tumours can invade and damage nearby tissues and organs. Malignant tumour cells may metastasise, entering the bloodstream or lymphatic system. When breast cancer cells metastasise outside the breast, they are often found in the lymph nodes under the arm (axillary lymph nodes). If the cancer has reached these nodes, it means that cancer cells may have spread to other lymph nodes or other organs, such as bones, liver, brain or lungs. Breast cancer metastasis of various organs also occurs without previous spreading to lymph nodes. Major and intensive research has been focussed on early detection, treatment and prevention of metastatic breast cancer.

The rational development of preventive, diagnostic and therapeutic strategies for women at risk for breast cancer would be aided by a molecular map of the tumorigenesis process. Relatively little is known of the molecular events that mediate the transition of normal breast cells to the various stages of breast cancer progression. Similarly, little is known of the molecular events that mediate the transition of cells from one stage of breast cancer to another, and finally to metastasis.

Molecular means of identifying the differences between normal, non-cancerous cells and cancerous cells have been the focus of intense study. The use of cDNA libraries to analyse differences in gene expression patterns in normal versus tumourigenic cells has been described. Gene expression patterns in human breast cancers have been described by Perou et al. (1999, Proc. Natl. Acad. Sci. USA, Vol. 96: 9212-9217), who studied gene expression between cultured human “normal” mammary epithelia cells (HMEC) and breast tissue samples by using microarrays comprising about 5000 genes. They used a clustering algorithm to identify differential patterns of expression in HMEC and tissue samples. Perou et al. (2000, Nature, Vol. 406: 747-752) described the use of clustered gene expression profiles to classify subtypes of human breast tumours. Hedenfalk et al. (2001, New Engl. J. Medicine, Vol. 344(8): 539-548) described gene expression profiles in BRCA1 mutation positive, BRCA2 mutation positive, and sporadic tumours. Using gene expression patterns to distinguish breast tumour subclasses and predict clinical implications is described by Sorlie et al. (2001, Proc. Natl. Acad. Sci USA, Vol. 98(19): 10869-10874) and West et al. (2001, Proc. Natl. Acad. Sci USA, Vol. 98(20): 11462-11467).

Based on the assumption that primary tumours may already contain genes that are predictive of metastastatic process, several groups performed genome wide microarray studies to identify expression profiles associated with the occurrence of distant relapses and poor survival. Several highly prognostic gene signatures were reported containing genes potentially involved in metastatic processes and/or markers of distant relapses. These studies mainly tackled overall relapses problems.

Searches aimed at identifying biological markers that would be involved in breast cancer metastasis in several tissues or organs have also been performed in the art. For this purpose, in vivo experiments using human breast cancer xenographs in nude mice were performed, as described below.

Kang et al. (2003, Cancer Cell, Vol. 3: 537-549) identified a set of genes potentially involved in breast cancer metastasis to bone, by comparing (i) the gene expression profile obtained from in vitro cultured cells of the MDBA-MB-231 human breast cancer cell line with (ii) the gene expression profile obtained from a subclone of the same cell line previously experimentally selected in vivo for their ability to form bone metastasis in mice. Using microarray gene expression analysis techniques, these authors showed that several genes were underexpressed and several other genes were overexpressed in the cell sublines selected for their ability to form bone metastasis in mice, as compared to the parental MDBA-MB-231 human breast cancer cell line. These authors concluded that, in the case of the human MDA-MB-231 cell line, cell functions that are relevant for metastasis to bone might be carried out by CXCR4, CTGF, IL-11 and OPN genes, with possible contributions of other genes.

Minn et al. (2005, Nature, Vol. 436(28): 518-524) used the same human parental MDA-MB-231 breast cancer cell line for selecting in vivo cell sublines having the ability to form lung metastasis in mice. Then, these authors have performed a transcriptomic microarray analysis of the highly and weakly lung-metastatic cell populations, with the view of identifying patterns of gene expression that would be associated with aggressive lung metastatic behaviour. A final list of 54 candidate lung metastagenicity and virulence genes was selected, twelve of them having been further identified for their significant association with lung-metastasis-free survival, including MMP1, CXCL1 and PTGS2.

In the studies reported above, the authors identified and functionally validated a set of genes that specifically mediate bone or lung metastasis in the animal model. The organ-specific gene signatures that were identified allowed to distinguish between (i) primary breast carcinomas that preferentially metastasized to bone or lung from (ii) those that metastasized elsewhere.

One study recently reported a molecular signature allowing for an bone-specific metastasis prognosis of human breast cancer. This work was performed by comparing primary breast tumors relapsing to bone to those relapsing elsewhere. The authors thereby identified a panel of genes associated to breast cancer metastasis to bone (Smid et al., 2006, J Clin Oncol, Vol. 24(15):2261-2267).

However, testing the organ-specific signature on mixed cohort of primary tumors did not allow robust classification of those tumors that gave rise to specific metastases versus those that did not. This is probably due to little predictive value of these gene signatures.

An early detection of metastasis in breast cancer patients is crucial for adapting the anti-cancer therapeutic treatment correspondingly, with the view of increasing the chances of long term disease-free survival.

However, because detection of metastasis in breast cancer patients, even if the said detection is performed at an early stage of metastasis, consists of a poor prognosis of the cancer outcome, there is an increasing need in the art for the availability of reliable methods for detecting the metastasis potentiality of a breast cancer tumour, for both medical treatment and medical survey purposes. There is also a need in the art for methods that would provide a prediction of the one or more tissues or organs in which the formation and development of a breast cancer metastasis would be likely to occur.

SUMMARY OF THE INVENTION

The present invention relates to methods and kits for predicting the occurrence of metastasis in patients affected with a breast cancer.

The breast cancer metastasis prediction methods of the invention comprise a step of determining, in a tumour tissue sample previously collected from a breast cancer patient to be tested the level of expression of one or more biological markers that are indicative of cancer progression towards metastasis, and more precisely, one or more biological markers that are indicative of cancer progression towards metastasis to specific tissues, and especially to bones, brain, lungs and liver.

This invention also relates to breast cancer metastasis prediction kits that are specifically designed for performing the metastasis prediction methods above.

This invention also pertains to methods for selecting one or more biological markers that are indicative of cancer progression towards metastasis in specific tissues, including bones, brain, lungs and liver.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1: Test of the bone and lung metastatic associated genes on primary tumors. Hierarchical clustering of relapsing primary breast carcinomas from a cohort of 27 patients was performed with the lung (A) and bone (B) metastatic signatures. Lung-metastasis-free survival and bone-metastasis-free survival analysis of corresponding patients was performed. Tumors from patients A2 (bottom line) express lung metastatic associated genes in a manner resembling lung relapses. Tumors from patients B2 (bottom line line) express bone metastatic associated genes in a manner resembling bone relapses.

FIG. 2: Segregation of primary breast carcinomas using the organ-specific signature. FIG. 2A depicts lung metastasis-free survival. FIG. 2B depicts bone metastasis-free survival. FIG. 2C depicts overall metastasis-free survival. Lung-metastasis-free survival (Kaplan Meier analysis) for 82 breast cancer patients who either expressed (FIG. 2A, corresponding to cluster A) or did not express (green line) the lung metastasis signature (cluster B+C).

FIG. 3: Performance of the six-gene lung metastasis signature in a series of 72 node-negative breast tumors (the CRH cohort) (A) Distribution of distant metastases (first and/or only metastatic sites) in the high-risk and low-risk groups identified by the six-gene signature (Chi² test). (B) Patients with tumors expressing the six-gene signature (high-risk group) had shorter lung-metastasis-free survival (log-rank test). (C and D) Kaplan-Meier curves of bone-metastasis-free survival and liver metastasis-free survival showed no difference between the high- and low-risk groups identified by the six-gene signature.

FIG. 4: Validation of the six-gene lung metastasis signature in 3 independent series of breast cancer patients. Lung-metastasis-free survival was analyzed for MSK (FIG. 4A), EMC (FIG. 4B) and NKI (FIG. 4C) cohorts (82, 344 and 295 patients respectively) and the combined cohort of 721 breast cancer patients (FIG. 4D). Kaplan-Meier analysis distinguished patients who expressed (high-risk group) and did not express (low-risk group) the six-gene signature. Patients with a high predicted risk of lung metastasis had shorter lung-metastasis-free survival.

FIG. 5: Integration of diverse clinicopathological markers and gene expression signatures for lung metastasis risk prediction. (A) Prediction of breast cancer lung metastasis is improved by using a combination of predictors derived from 2 distinct models. (B) Distribution of lung metastases in the combined cohort of 721 breast cancer patients (MSK/EMC/NKI) according to the clinically and experimentally derived signatures. Patients that are negative for both signatures are shown in black; those with divergent assignement are indicated in blue; and patients found positive for both signatures are shown in green. The six-gene and LMS signatures showed 85% agreement in outcome classification of breast cancer patients with respect to lung metastasis (Kappa coefficient=0.57). (B) Kaplan-Meier analysis of breast cancer patients (n=721) according to the six-gene and MDA-derived lung metastasis signatures.

FIG. 6: Test of bone metastatic associated genes on primary tumors: Hierarchical clustering of relapsing primary breast carcinomas from a cohort of patients was performed with the eleven-gene bone metastatic signature. Bone metsatsis-free survival analysis of corresponding patients was performed.

DETAILED DESCRIPTION OF THE INVENTION

Methods allowing an early prediction of the likelihood of development of metastasis in breast cancer patients are provided by the present invention.

Particularly, it is provided herein methods and kits allowing prediction of the occurrence of metastasis to one or more specific tissue or organ in breast cancer patients, notably in bone, lung, liver and brain tissues or organs.

According to the present invention, highly reliable tissue-specific sets of biological markers that are indicative of a high probability of metastasis occurrence in breast cancer patients have been identified.

The identification of these highly reliable tissue-specific sets of biological markers was permitted, due to the use of a highly accurate method for the screening of such metastasis biological markers that is described below in the present specification.

Thus, an object of the present invention consists of an in vitro method for predicting the occurrence of metastasis in a patient affected with a breast cancer, comprising the steps of:

-   -   a) providing a breast tumour tissue sample previously collected         from the patient to be tested;     -   b) determining, in the said breast tumour tissue sample, the         expression of one or more biological markers that are indicative         of an occurrence of metastasis in one or more tissue or organ,         wherein the said one or more biological markers are selected         from the group consisting of:         -   (i) one or more biological markers indicative of an             occurrence of metastasis in the bone tissue that are             selected from the group consisting of: CLEC4A, MFNG, NXF1,             FAM78A, KCTD1, BAIAP2L1, PTPN22, MEGF10, PERP, PSTPIP1,             FLI1, COL6A2, CD4, CFD, ZFHX1B, CD33, LST1, MMRN2, SH2D3C,             RAMPS, FAM26B, ILK, TM6SF1, C10orf54, CLEC3B, IL2RG,             HOM-TES-103, ZNF23, STK35, TNFAIP8L2, RAMP2, ENG, ACRBP,             TBC1D10C, C11orf48, EBNA1BP2, HSPE1, GAS6, HCK, SLC2A5,             RASA3, ZNF57, WASPIP, KCNK1, GPSM3, ADCY4, A1F1, NCKAP1,             AMICA1, POP7, GMFG, PPM1M, CDGAP, GIMAP1, ARHGAP9, APOB48R,             OCIAD2, FLRT2, P2RY8, RIPK4, PECAM1, URP2, BTK, APBB1IP,             CD37, STARD8, GIMAP6, E2F6, WAS, HLA-DQB1, HVCN1, L0056902,             ORC5L, MEF2C, PLCL2, PLAC9, RAC2, SYNE1, DPEP2, MYEF2,             HSPD1, PSCD4, NXT1, LOC340061, ITGB3, AP1S2, SNRPG, CSF1,             BIN2, ANKRD47, LIMS2, DARC, PTPN7, MSH6, GGTA1, LRRC33,             GDPD5, CALC0001, FAM110C, BCL6B, LOC641700, ARHGDIB, DAAM2,             TNFRSF14, TPSAB1, CSF2RA, RCSD1, FLJ21438, LOC133874, GSN,             SLIT3, FYN, NCF4, PTPRC, EVI2B, SCRIB, C11orf31, LOC440731,             TFAM, ARPC5L, PARVG, GRN, LMO2, CRSP8, EHBP1L1, HEATR2,             NAALADL1, LTB, STRBP, FAM65A, ADARB1, TMEM140, DENND1C,             PRPF19, CASP10, SLC37A2, RHOJ, MPHOSPH10, PPIH, RASSF1,             HCST, C16orf54, EPB41L4B, LRMP, LAPTM5, PRDM2, CYGB, LYCAT,             ACP5, CMKLR1, UBE1L, MAN2C1, TNFSF12, C7orf24, Cxorf15,             CUL1, SMAD7, ITGB7, APOL3, PGRMC1, PPA1, YES1, FBLN1, MRC2,             PTK9L, LRP1, IGFBP5, WDR3, GTPBP4, SPI1, SELPLG, OSCAR,             LYL1, POLR2H, YWHAQ, ISG20L2, LGI14, KIF5B, NGRN, TYROBP,             C5orf4, COX7A2, S100A4, MATK, TMEM33, DOK3, LOC150166,             CIRBP, NIN, C10orf72, FMNL1, FATS, CHKB/CPT1B, SNRPA1,             GIMAP4, C20orf18, LTBP2, GABS, NQO1, MARCH2, MYO1F, CDS1,             SRD5A1, C20orf160, SLAMF7, ACTL6A, ABP1, RAE1, MAF, SEMA3G,             P2RY13, ZDHHC7, ERG, CLEC10A, INTS5, MYO15B, CTSW, PILRA,             HN1, SCARA5, PRAM1, EBP, SIGLEC9, LGP1, DGUOK, GGCX, RABL5,             ZBTB16, NOP5/NOP58, CCND2, CD200, EPPK1, DKFZp586C0721,             CCT6A, RIPK3, ARHGAP25, GNAI2, USP4, FAHD2A, LOC399959,             LOC133308, HKDC1, CD93, GTF3C4, ITGB2, ELOVL6, TGFB111,             ASCC3L1, FES, AACS, ATP6VOD2, TMEM97, NUDT15, ATP6V1B2,             CCDC86, FLJ10154, SCARF2, PRELP, ACHE, GIMAP8, PDE4DIP,             NKG7, C20orf59, RHOG, TRPV2, TCP1, TNRC8, TNS1, IBSP, MMP9,             NRIP2, OLFML2B, OMD, WIF1, ZEB2, ARL8, COL12A1, EBF and             EBF3;         -   (ii) one or more biological markers indicative of an             occurrence of metastasis in the lung tissue that are             selected from the group consisting of: SC2, HORMAD1,             PLEKHG4, ODF2L, C21orf91, TFCP2L1, TTMA, CHODL, CALB2, UGT8,             LOC146795, C1orf210, SIKE, ITGB8, PAQR3, ANP32E,             C20orf42/FERMT1, ELAC1, GYLTL1B, SPSB1, CHRM3, PTEN, PIGL,             CHRM3, CDH3;         -   (iii) one or more biological markers indicative of an             occurrence of metastasis in the liver tissue that are             selected from the group consisting of: TBX3, SYT17,             LOC90355, AGXT2L1, LETM2, LOC145820, ZNF44, IL20RA, ZMAT1,             MYRIP, WHSC1L1, SELT, GATA2, ARPC2, CAB39L, SLCI6A3, DHFRL1,             PRRT3, CYP3A5, RPS6KA5, KIAA1505, ATP5S, ZFYVE16, KIAA0701,             PEBP1, DDHD2, WWP1, CCNL1, ROBO2, FAM111B, THRAP2, CRSP9,             KARCA1, SLC16A3, ARID4A, TCEAL1, SCAMP1, KIAAO701, EIF5A,             DDX46, PEX7, BCL2L11, YBX1, UBE21, REXO2, AXUD1, C10orf2,             ZNF548, FBXL16, LOC439911, LOC283874, ZNF587, FLJ20366,             KIAAO888, BAG4, CALU, KIAA1961, USP30, NR4A2, FOXA1, FBXO15,             WNK4, CDIPT, NUDT16L1, SMAD5, STXBP4, TTC6, LOC113386TSPYL1,             CIP29, C8orf1SYDE2, SLC12A8, SLC25A18, C7, STAU2, TSC22D2,             GADD45G, PHF3, TNRC6C, TCEAL3, RRN3, C5orf24, AHCTF1,             LOC92497; and         -   (iv) one or more biological markers indicative of an             occurrence of metastasis in the brain tissue that are             selected from the group consisting of: LOC644215, BAT1,             GPR75, PPWD1, INHA, PDGFRA, MLL5, RPS23, ANTXR1, ARRDC3,             PTK2, SQSTM1, METTL7A, NPHP3, PKP2, DDX31, FAM119A, LLGL2,             DDX27, TRA16, HOXB13, GNAS, CSPP1, COL8A1, RSHL1, DCBLD2,             UBXD8, SURF2, ZNF655, RAC3, AP4M1, HEG1, PCBP2, SLC30A7,             ATAD3A/ATAD3B, CHI3L1, MUC6, HMG20B, BCL7A, GGN, ARHGEF3,             PALLD, TOP1, PCTK1, C20orf4, ZBTB1, MSH6, SETD5, POSTN,             MOCS3, GABPA, ZSWIM1, ZNHIT2, LOC653352, ELL, ARPC4, ZNF277,             VAV2, HNRPH3, LHX1, FAM83A, DIP2B, RBM10, PMPCA, TYSND1,             RAB4B, DLC1, KIAA2018, TES, TFDP2, C3orf10, ZBTB38, PSMD7,             RECK, JMJD1C, F1120273, CENPB, PLAC2, C6orf111, ATP10D,             RNF146, XRRA1, NPAS2, APBA2BP, WDR34, SLK, SBF2, SON, MORC3,             C3orf63, WDR54, STX7, ZNF512, KLHL9, LOC284889, ETV4,             RMND5B, ARMCX1, SLC29A4, TRIB3, LRRC23, DDIT3, THUMPD3,             MICAL-L2, PA2G4, TSEN54, LAS1L, MEA1, S100PBP, TRAF2,             EMILIN3, KIAA1712, PRPF6, CHD9, JMJD1B, ANKS1A, CAPN5, EPC2,             WBSCR27, CYB561, LLGL1, EDD1.     -   c) predicting the occurrence of metastasis in one or more tissue         or organ when one or more of the said biological markers has         (have) a deregulated expression level, as compared to its         corresponding expression level measured in a breast tumour         sample of a patient that has not undergone metastasis in the         corresponding tissue or organ.

As previously mentioned herein, prior art studies disclosed several gene signatures containing genes potentially involved in metastatic processes and/or markers of distant relapses. However, these prior art studies tackled overall relapses problems. As there are multiple types of metastases and potentially multiple distinct pathological processes leading to metastases, these prior art studies suffered for lack of accuracy.

Notably, according to a plurality of these prior art methods, selection of metastasis-specific biological markers was performed by human marker expression analysis in artificial in vivo systems, namely in non-human animals, especially in mice.

Further, the screening of metastasis-specific biological markers were generally performed using artificial human cell systems, namely established human cancer cell lines, wherein expression artefacts of one or more genes or proteins cannot be excluded. The probability of introduction of biological markers expression artefacts was further increased by various features of the screening methods which were used, including the selection of multiple human cell sublines having a metastatic potency derived from the parental cell line, by reiterating in vivo cycles of cell administration/selection in non-human animal systems, including mice.

Still further, according to these prior art techniques, once pertinent cell sublines were finally selected for their high metastatic potency in non-human animals, differential gene expression analysis was performed by comparing the expression levels of genes between (i) the parental human breast cancer cell line and (ii) the various cell sublines having a metastatic potency.

In view of improving the accuracy of the prior art techniques of selecting metastasis-specific markers for breast cancer, the inventors have designed an original method for selecting highly reliable tissue-specific biological markers of metastasis in breast cancer, using a whole human system of analysis and including, among other features, a step of comparing the expression level of candidate biological markers between (i) a metastatic tissue or organ of interest and (ii) one or more distinct metastatic tissue(s) or organ(s), thus allowing a high selectivity and statistical relevance of the tissue-specific metastatic biological markers that are positively selected, at the end of the marker selection method.

As it is shown in the examples herein, when using a marker selection method comprising a step of comparing the expression level of candidate biological markers between (i) a metastatic tissue or organ of interest selected from the group consisting of bone, lung, liver and brain and (ii) all the other metastatic tissue(s) or organ(s) selected from the group consisting of bone, lung, liver and brain, the inventors have identified tissue-specific breast cancer metastasis biological markers endowed with a high statistical relevance, with P values always lower than 1.10⁻⁴, the said P values being lower than 10⁻⁶ for the most statistically relevant biological markers. Statistical relevancy of the biological markers primarily selected was fully corroborated by Kaplan-Meier analysis, after having assayed for the expression of the said tissue-specific markers in tumour tissue samples of breast cancer patients, as it is shown in the examples herein.

As intended herein; a “biological marker” encompasses any detectable product that is synthesized upon the expression of a specific gene, and thus includes gene-specific mRNA, cDNA and protein.

As used herein, a “biological marker indicative of an occurrence of metastasis”, or a “metastasis-specific marker”, encompasses any biological marker which is differentially expressed in breast tumors that generate metastasis, or will generate metastasis, in a specific given tissue or in a specific given organ, as compared to the expression of the same biological marker in breast tumors that do not generate metastasis, or will not generate metastasis, in the said specific given tissue or in the said specific given organ. Preferably, tissues and organs are selected from the group consisting of bone, lung, liver and brain.

The terms “tissue-specific” marker and “tissue metastasis-specific” marker are used interchangeably herein. Similarly, the terms “organ-specific” marker and “organ metastasis-specific” marker are used interchangeably herein.

As intended herein, a “prediction of the occurrence of metastasis” does not consist of an absolute value, but in contrast consists of a relative value allowing to quantify the probability of occurrence of a metastasis to one or more specific tissue(s) or organ(s), in a breast cancer patient. In certain embodiments, the prediction of the occurrence of metastasis is expressed as a statistical value, including a P value, as calculated from the expression values obtained for each of the one or more biological markers that have been tested.

As intended herein, a “tumour tissue sample” encompasses (i) a global primary tumour (as a whole), (ii) a tissue sample from the center of the tumour, (iii) a tissue sample from a location in the tumour, other than the center of the tumour and (iv) any tumor cell located outside the tumor tissue per se. In certain embodiments, the said tumour tissue sample originates from a surgical act of tumour resection performed on the breast cancer patient. In certain other embodiments, the said tissue sample originates from a biopsy surgical act wherein a piece of tumour tissue is collected from the breast cancer patient for further analysis. In further embodiments, the said tumor sample consists of a blood sample, including a whole blood sample, a serum sample and a plasma sample, containing tumour cells originating from the primary tumor tissue, or alternatively from metastasis that have already occurred. In still further embodiments, the said tumor sample consists of a blood sample, including a whole blood sample, a serum sample and a plasma sample, containing tumor proteins produced by tumor cells originating from the primary tumor tissue, or alternatively from metastasis that have already occurred.

The various biological markers names specified herein correspond to their internationally recognised acronyms that are usable to get access to their complete amino acid and nucleic acid sequences, including their complementary DNA (cDNA) and genomic DNA (gDNA) sequences. Illustratively, the corresponding amino acid and nucleic acid sequences of each of the biological markers specified herein may be retrieved, on the basis of their acronym names, that are also termed herein “gene symbols”, in the GenBank or EMBL sequence databases. All gene symbols listed in the present specification correspond to the GenBank nomenclature. Their DNA (cDNA and gDNA) sequences, as well as their amino acid sequences are thus fully avaialble to the one skilled in the art from the GenBank database, notably at the following Website address: “http://www.ncbi.nlm.nih.gov/”. The same sequences may also be retrieved from the Hugo Gene Nomenclature Committee (HGCN) database that is available at the following Website address: http://www.gene.ucl.ac.uk/nomenclature/.

At step b) of the in vitro prediction method according to the invention, one or more of the specified biological markers is (are) quantified. Quantification of a biological marker includes detection of the expression level of the said biological marker. Detection of the expression level of a specific biological marker encompasses the assessment of the amount of the corresponding specific mRNA or cDNA that is expressed in the tumour tissue sample tested, as well as the assessment of the amount of the corresponding protein that is produced in the said tumour tissue sample.

At the end of step b) of the method according to the invention, a quantification value is obtained for each of the one or more biological markers that are used.

As it has been previously specified, specific embodiments of step b) include:

-   -   (i) quantifying one or more biological markers by immunochemical         methods, which encompasses quantification of one or more protein         markers of interest by in situ immunohistochemical methods on a         tumor tissue sample, for example using antibodies directed         specifically against each of the said one or more protein         markers.     -   (ii) quantifying one or more biological markers by gene         expression analysis, which encompasses quantification of one or         more marker mRNAs of interest, for example by performing a         Real-Time PCR Taqman PCR analysis, as well as by using         specifically dedicated DNA microarrays, i.e. DNA microarrays         comprising a substrate onto which are bound nucleic acids that         specifically hybridize with the cDNA corresponding to every one         of the biological markers of interest, among the biological         markers listed herein.

In certain other embodiments of the method, step b) consists of quantifying, in a tumor tissue sample, the expression level of one or more marker genes among those specified above. Generally, the assessment of the expression level for a combination of at least two marker genes is performed. In these embodiments of step b) of the method, what is obtained at the end of step b) consists of the expression level values found for each marker gene (nucleic acid or protein expression level) specifically found in cells contained in the tumour tissue sample.

The expression level of a metastasis-specific biological marker according to the present invention may be expressed as any arbitrary unit that reflects the amount of the corresponding mRNA of interest that has been detected in the tissue sample, such as intensity of a radioactive or of a fluorescence signal emitted by the cDNA material generated by PCR analysis of the mRNA content of the tissue sample, including (i) by Real-time PCR analysis of the mRNA content of the tissue sample and (ii) hybridization of the amplified nucleic acids to DNA microarrays. Preferably, the said expression level value consists of a normalised relative value which is obtained after comparison of the absolute expression level value with a control value, the said control value consisting of the expression level value of a gene having the same expression level value in any breast tissue sample, regardless of whether it consists of normal or tumour breast tissue, and/or regardless whether it consists of a non-metastatic or a metastatic breast tissue. Illustratively, the said control value may consist of the amount of mRNA encoding the TATA-box-binding protein (TBP), as it is shown in the examples herein.

Alternatively, the said expression level may be expressed as any arbitrary unit that reflects the amount of the protein of interest that has been detected in the tissue sample, such as intensity of a radioactive or of a fluorescence signal emitted by a labelled antibody specifically bound to the protein of interest. Alternatively, the value obtained at the end of step b) may consist of a concentration of protein(s) of interest that could be measured by various protein detection methods well known in the art, such as. ELISA, SELDI-TOF, FACS or Western blotting.

Because every one of the biological markers that are specified herein consists of a biological marker (i) that is specifically expressed, including at a given expression level, exclusively in a given breast cancer metastatic tissue or organ and (ii) that is expressed at another expression level, in a distinct breast cancer metastatic tissue or organ, then the sole quantification of its expression in a tumour tissue sample originating from a primary tumour specimen allows to predict whether the breast cancer-bearing patient is likely to undergo generation of metastasis in the said tissue or organ.

Additionally, quantifying the said one or more biological markers that are specified herein brings further prediction data relating to the probability of occurrence of metastasis in one or more specific tissue or organ in a breast cancer-bearing patient, since the probability of occurrence of metastasis increases with an increased deregulation of the expression level of the said one or more biological markers tested, as compared to their control expression level that is previously measured in a breast tumor sample from a patient that has not undergone metastasis, at least in the tissue or organ of interest that is considered.

Thus, as used herein, a biological marker of interest having a “deregulated expression level” consists of a metastasis-specific biological marker for which is found, when performing step b) of the in vitro prediction method according to the invention, an expression level value that is distinct from the expression level value (that may also be termed the “control” expression value) for the said biological marker that has been previously determined (i) in tumor tissue samples originating from breast cancer patients that have never undergone metastasis, or alternatively (ii) in tumor tissue samples originating from breast cancer patients that have never undergone metastasis in the tissue or organ from which the said biological marker is metastasis-specific. For performing step c) of the prediction method according to the invention, the one skilled in the art may refer to the deregulated expression values for each of the metsatasis-specific markers described herein, as they are found notably in Tables 1, 2, 5 and 8.

As it is shown in the examples, every one of the biological markers listed herein is highly relevant for predicting the occurrence of metastasis in a specific tissue, since the markers having the lowest statistical relevance possess a P value lower than 1.10⁻⁴.

Further, accuracy of the metastasis prediction increases, at step c) of the method, when more than one tissue-specific biological marker for a given tissue or organ is detected and/or quantified at step b).

Thus, in preferred embodiments of the prediction method according to the invention, more than one biological marker for a given tissue or organ is detected and/or quantified, at step b) of the method.

The more biological markers specific for a given tissue or organ are quantified at step b) of the method, the more accurate are the prediction results that are obtained at step c) of the said method.

Quantifying a plurality of biological markers specific for a given tissue or organ at step b) of the method allows to generate an experimental expression profile of the said plurality of markers, which expreimental expression profile is then compared with at least one reference expression profile that has been previously determined from tissue-specific metastasis patients. Illustratively, if bone metastasis is suspected in the patient tested, then the experimental expression profile that is generated from the results of quantification of the bone metastasis-specific marker genes used at step b) of the method is compared with the pre-existing reference expression profile corresponding to bone metastasis, for prediction. Preferably, the experimental expression profile of the bone-specific metastasis markers is compared with reference expression profiles of the same genes that have been previously determined in patients having bone metastasis, as well as with reference expression profiles obtained from patients having other tissue- or organ-specific metastasis, so as to ensure that the experimental expression profile is the most close from the reference expression profile predetermined from patients having bone metastasis.

In certain embodiments of the prediction method, step b) comprises quantifying at least one tissue-specific biological marker for each tissue or organ. Illustratively, in those embodiments of the method, step b) comprises quantifying (i) at least one bone-specific biological marker, (ii) at least one lung-specific biological marker, (iii) at least one liver-specific biological marker and (iv) at least one brain-specific biological marker.

In certain embodiments of the method, step b) comprises quantifying at least two tissue-specific biological markers for a given tissue or organ. The higher the number of tissue-specific markers for a given tissue or organ are quantified at step b), the more accurate is the prediction of occurrence of metastasis in the said given tissue in the breast cancer-bearing patient tested.

Thus, in certain embodiments of the prediction method according to the invention, the number of biological markers tested for a given tissue or organ is of at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165, 166, 167, 168, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191, 192, 193, 194, 195, 196, 197, 198, 199; 200, 201, 202, 203, 204, 205, 206, 207, 208, 209, 210, 211, 212, 213, 214, 215, 216, 217, 218, 219, 220, 221, 222, 223, 224, 225, 226, 227, 228, 229, 230, 231, 232, 233, 234, 235, 236, 237, 238, 239, 240, 241, 242, 243, 244, 245, 246, 247, 248, 249, 250, 251, 252, 253, 254, 255, 256, 257, 258, 259, 260, 261, 262, 263, 264, 265, 266, 267, 268, 269, 270, 271, 272, 273, 274, 275, 276, 277, 278, 279, 280, 281, 282, 283, 284, 285, 286, 287, 288, 289, 290, 291, 292, 293, 294, 295, 296, 297, 298, 299 or 300 distinct tissue-specific biological markers for a given tissue or organ selected from the group consisting of the tissue-biological markers disclosed in the present specification, the maximum number of distinct tissue-specific biological markers for a given tissue or organ being limited by the number of markers that are disclosed herein for the said given tissue or organ.

Any combination of two or more of the biological marker described herein is fully encompassed by the present invention.

When a plurality of biological markers for each of the tissues or organs are quantified, at step b) of the method, then experimental expression profiles of the patient tested may be generated, that are then compared to the reference expression profiles of the same biological markers, so as to determine to which reference expression profile the experimental expression profile is the most similar, and thus which tisue- or organ-specific metastasis may eventually be predicted.

In some embodiments of the prediction method according to the invention, step c) may be performed by the one skilled in the art by calculating a risk index of organ-specific metastasis of the patient tested, starting from the expression level values of the one or more biological markers that ave been determined at step b). Numerous methods for calculating a risk index are well known from the one skilled in the art.

Illustratively, the one skilled in the art may calculate the risk index of the patient tested, wherein the said risk index is defined as a linear combination of weighted (or not, depending one the genes tested) expression level values with the standardized Cox's regression coefficient as the weight.

Risk  index    = A?w_(i)x_(i) ?indicates text missing or illegible when filed

wherein:

-   -   A is a constant     -   w_(i) is the standardized Cox's regression coefficient for the         markers     -   x_(i) is the expression value of the marker (log scale)     -   n is the number of genes to predict the risk

The threshold is determined from the ROC curve of the training set to ensure the highest sensitivity and specificity. The constant value A is chosen to center the threshold of the risk index to zero. Patients with positive risk index are classified into the high risk of organ-specific group and patients with negative risk index are classified into the low risk of organ-specific group.

Illustrative embodiments of the prediction method according to the invention, wherein step c) is performed by calculating a risk index of organ-specific metastasis of the patient tested are illustrated in Tables 9, 10, 11 and 12.

Table 9 illustrates the predictive values of various lung-specific biological markers that may be used in the method according to the invention.

Details of Table 9 are given hereunder.

Cohort: EMC-344 TP

Summary of Results:

-   -   Number of genes significant at 0.99 level of the univariate         test: 23     -   Genes significantly associated with survival:     -   Table 9—Sorted by p-value of the univariate test.     -   The first 23 genes are significant at the nominal 0.99 level of         the univariate test     -   Hazard ratio is the ratio of hazards for a two-fold change in         the gene expression level.     -   It is equal to exp(b) where b is the Cox regression coefficient.         SD is the standard deviation of the log 2 of the gene expression         level.         Table 10 illustrates the predictive values of various         lung-specific biological markers that may be used in the method         according to the invention. Details of Table 10 are given         hereunder.

Cohort: MSK-82 TP

Summary of Results:

-   -   Number of genes significant at 0.99 level of the univariate         test: 23     -   Genes significantly associated with survival:     -   Table 10—Sorted by p-value of the univariate test.     -   The first 23 genes are significant at the nominal 0.99 level of         the univariate test     -   Hazard ratio is the ratio of hazards for a two-fold change in         the gene expression level.2 of the gene expression level.     -   It is equal to exp(b) where b is the Cox regression coefficient.         SD is the standard deviation of the log         Table 11 illustrates the predictive values of various         lung-specific biological markers that may be used in the method         according to the invention. Details of Table 11 are given         hereunder.

Cohort: NKI-295

Summary of Results:

-   -   Number of genes significant at 0.9 level of the univariate test:         20     -   Genes significantly associated with survival:     -   Table 11—Sorted by p-value of the univariate test.     -   The first 20 genes are significant at the nominal 0.9 level of         the univariate test     -   Hazard ratio is the ratio of hazards for a two-fold change in         the gene expression level. 2 of the gene expression level.     -   It is equal to exp(b) where b is the Cox regression coefficient.         SD is the standard deviation of the log 2 of the gene expression         level.         Table 12 illustrates the predictive values of various         bone-specific biological markers that may be used in the method         according to the invention. Details of Table 12 are given         hereunder.

Cohort: NKI-295

Summary of Results:

-   -   Number of genes significant at 0.99 level of the univariate         test: 51     -   Genes significantly associated with survival:     -   Table 1—Sorted by p-value of the univariate test.     -   The first 51 genes are significant at the nominal 0.99 level of         the univariate test     -   Hazard ratio is the ratio of hazards for a two-fold change in         the gene expression level.     -   It is equal to exp(b) where b is the Cox regression coefficient.         SD is the standard deviation of the log 2 of the gene expression         level.

Also, the 40 highest ranking bone-specific biological markers that have been identified according to the present invention are shown in Table 13 hereunder.

In certain embodiments of the prediction method according to the invention, the one or more bone-specific biological markers that are quantified at step b) are selected from the group consisting of CLEC4A, MFNG, NXF1, FAM78A, KCTD1, BAIAP2L1, PTPN22, MEGF10, PERP, PSTPIP1, FL11, COL6A2, CD4, CFD, ZFHX1B, CD33, MMRN2, LST1, SH2D3C and RAMPS. Those bone-specific markers possess a high statistical relevance for predicting the occurrence of metastasis in bone tissue, with P values obtained after DNA microarray analysis that are always lower than 10⁻⁶, as shown in Table 2

In certain embodiments of the prediction method according to the invention, the one or more lung-specific biological markers that are quantified at step b) are selected from the group consisting of DSC2, HORMAD1, PLEKHG4, ODF2L, c21orf91, TFCP2L1, CHODL, CALB2, UGT8, c1orf210, SIKE, ITGB8, PAQR3, ANP32E, KIND1, ELAC1, GYLTL1B, SPSB1, PTEN and CHRM3. Those lung-specific markers possess a high statistical relevance for predicting the occurrence of metastasis in lung tissue or organ, with P values obtained after DNA microarray analysis that are always lower than 10⁻⁴, as shown in Table 2

In certain embodiments of the prediction method according to the invention, the one or more liver-specific biological markers that are quantified at step b) are selected from the group consisting of TBX3, c5orf30, AGXT2L1, LETM2, ZNF44, IL20RA, ZMAT1, MYRIP, WHSC1L1, SELT, GATA2, DHFRL1, ARPC2, SLC16A3, GNPTG, PRRT3, RPS6KA5, K1 AA1505, ZFYVE16 and K1AA0701. Those liver-specific markers possess a high statistical relevance for predicting the occurrence of metastasis in liver tissue or organ, with P values obtained after DNA microarray analysis that are always lower than 10⁻⁵, as shown in Table 2

In certain embodiments of the prediction method according to the invention, the one or more brain-specific biological markers that are quantified at step b) are selected from the group consisting of PPWD1, INHA, PDGFRA, MLL5, RPS23, ANTXR1, ARRDC3, METTL7A, NPHP3, PKP2, DDX27, TRA16, HOXB13, CSPP1, RSHL1, DCBLD2, UBXD8, SURF2, ZNF655 and RAC3. Those brain-specific markers possess a high statistical relevance for predicting the occurrence of metastasis in brain tissue or organ, with P values obtained after DNA microarray analysis that are always equal to, or lower than, 10⁻⁵, as shown in Table 2.

In certain other embodiments of the prediction method according to the invention, the one or more tissue-specific biological markers are selected from the following groups of markers:

-   -   (i) the group of bone metastasis-specific markers consisting of         KTCD1, BAIAP2L1, PERP, CFD, CD4, COL6A2, FLI1, PSTPIP1, MGF10,         PTPN22, FAM78A, NXF1, MFNG and CLEC4A;     -   (ii) the group of lung metastasis-specific markers consisting of         KIND1, ELAC1, ANP32E, PAQR3, ITGB8, c1orf210, SIKE, UGT8, CALB2,         CHODL, c21orf91, TFCP2L1, ODF2L, HORMAD1, PLEKHG4 and DSC2;     -   (iii) the group of liver metastasis-specific makers consisting         of GATA2, SELT, WHSC1L1, MYRIP, ZMAT1, IL20RA, ZNF44, LETM2,         AGXT2L1, c5orf30 and TBX3.     -   (iv) the group of brain metastasis-specific markers consisting         of PPWD1, PDGFRA, MLL5, RPS23, ANTXR1, ARRDC3, METTL7A, NPHP3,         RSHL1, CSPP1, HOXB13, TRA16, DDX27, PKP2 and INHA.

In still other embodiments of the prediction method according to the invention, the one or more tissue-specific biological markers are selected from the following groups of markers:

-   -   (i) the group of bone metastasis-specific markers consisting of         BAIAP2L1, PERP, CFD, CD4, COL6A2, FLI1, PSTPIP1, MGF10, PTPN22,         FAM78A, NXF1, MFNG and CLEC4A;     -   (ii) the group of lung metastasis-specific markers consisting of         KIND1, ANP32E, ITGB8, UGT8, TFCP2L1, HORMAD1 and DSC2;     -   (iii) the group of liver metastasis-specific makers consisting         of GATA2, WHSC1L1, LETM2, AGXT2L1 and TBX3.     -   (iv) the group of brain metastasis-specific markers consisting         of PPWD1, PDGFRA, ANTXR1, ARRDC3 and DDX27.

In yet further embodiments of the prediction method according to the invention, the one or more lung-specific biological markers that are detected and/or quantified at step b) are selected from the group consisting of DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.

In still further embodiments of the prediction method according to the invention, the one or more bone-specific biological markers that are detected and/or quantified at step b) are selected from the group consisting of KCNK1, CLEC4A, MFNG, NXF1, PTPN22, PERP, PSTPIP1, FL11, COL6A2, CD4 and CFD. Predictive results of these bone-specific biological markers are shown in Table 8 hereunder.

As it is shown in examples 3 to 6 herein, the said lung-specific markers possess a high statistical relevance for predicting the occurrence of metastasis in lung tissue or organ, with P values obtained after DNA microarray analysis that are always lower than 10⁻⁴, as shown notably in Table 5.

The lung-specific markers DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1 are all up-regulated in individuals affected with breast cancer and bearing lung metastasis, as compared with breast cancer patients who have no lung metastasis or with individuals who are not affected with a breast cancer, as shown in Table 5.

As shown in examples 3 to 6 herein, the DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1 lung-specific markers consists of a six-gene signature which is predictive of selective breast cancer relapse to the lungs.

As shown in the examples herein, this six-gene signature (DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1) was generated from a series of lymph node-negative breast cancer patients who did not receive any neoadjuvant or adjuvant therapy to allow the analysis of the signature prognostic impact along with the natural history of the disease. The predictor would thus not be influenced by factors related to systemic treatment.

This six-gene signature was validated in three independent cohort of breast cancers consisting of a total of 721 patients, as detailed hereafter and as illustrated in the examples herein. The said six-gene signature was thus validated in two independent data sets of patients of early stage (n=295 and 344) generated from two distinct microarray platforms and a third series of locally advanced breast cancer patients (n=82). In all tested individual series and in the combined cohort (n=721), the six gene signature had a strong predictive ability for breast cancer lung metastasis.

The results described in the examples herein show that the said six-gene signature improves risk stratification independently of known standard clinical parameters and previously established lung metastasis signature based on an experimental model.

Although there is no targeted therapy for lung metastasis, such as bisphosphonates for bone metastasis, the knowledge of organ-specific metastasis has been emphasized the last few years and might lead to targeted therapeutics in the near future. By delineating the risk for lung metastasis based on gene signatures, it might be possible that these high-risk breast cancer patients may benefit from these therapies targeting specific secondary failures.

Thus, in a further embodiment of the prediction method according to the invention, step b) consists of determining, in the breast tumour tissue sample, the expression of one or more biological markers that are indicative of an occurrence of metastasis in the lung tissue that are selected from the group consisting of DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.

In the above-embodiment of the prediction method according to the invention, the expression of 2, 3, 4, 5 or all of the six lung-specific markers is determined, i.e. detected end/or quantified.

In certain embodiments of the prediction method according to the invention, every one of the tissue-specific biological markers comprised in each group of markers disclosed herein is submitted to quantification. In those embodiments, step b) comprises quantifying every biological marker contained in each group of markers disclosed herein. More precisely, according to those embodiments of the method, step b) comprises quantifying every biological marker contained in (i) one group of bone-specific markers, (ii) one group of lung-specific markers, (iii) one group of liver-specific markers and (iv) one group of brain-specific markers, selected among the various groups of (i) bone-specific markers, (ii) lung-specific markers, (iii) liver-specific markers and (iv) brain-specific markers disclosed in the present specification.

Indeed, the use of every possible combination of at least two metastasis-specific biological markers, that are selected from the group consisting of all the metastasis-specific biological markers disclosed in the present specification, is encompassed herein, for the purpose of performing the in vitro prediction method according to the invention.

Preferably, the use of every possible combination of four or more metastasis-specific biological markers, provided that each possible combination comprises (i) one or more bone metastasis-specific biological marker, (ii) one or more lung metastasis-specific biological marker, (iii) one or more liver metastasis-specific biological marker and (iv) one or more liver metastasis-specific biological marker, is encompassed herein, for the purpose of performing the in vitro prediction method according to the invention.

Thus, in certain embodiments of the prediction method according to the invention, at least one biological marker selected from each of the groups (i), (ii), (iii) and (iv) is quantified at step b).

In certain embodiments of the prediction method, all biological markers from specific groups (i), (ii), (iii) and (iv) are quantified at step b).

Thus, in certain embodiments of the prediction method according to the invention, step b) consists of determining (i.e. detecting and/or quantifying), in the breast tumour tissue sample, the expression of every one of the following lung-specific markers: DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.

Also, in certain embodiments of the prediction method according to the invention, step b) consists of determining (i.e. detecting and/or quantifying), in the breast tumor sample, the expression of every one of the following bone-specific markers: KCNK1, CLEC4A, MFNG, NXF1, PTPN22, PERP, PSTPIP1, FL11, COL6A2, CD4 and CFD.

At step b), the said one or more biological markers may be quantified by submitting the said breast tumour tissue sample to a gene expression analysis method.

At step b), the said one or more biological markers may alternatively be quantified by submitting the said breast tumour tissue sample to an immunohistochemical analysis method.

General methods for quantifying the tissue-specific biological markers disclosed herein are detailed below.

General methods for quantifying biological markers

Any one of the methods known by the one skilled in the art for quantifying a protein biological marker or a nucleic acid biological marker encompassed herein may be used for performing the metastasis prediction method of the invention. Thus any one of the standard and non-standard (emerging) techniques well known in the art for detecting and quantifying a protein or a nucleic acid in a sample can readily be applied.

Such techniques include detection and quantification of nucleic acid biological markers with nucleic probes or primers.

Such techniques also include detection and quantification of protein biological markers with any type of ligand molecule that specifically binds thereto, including nucleic acids (e.g. nucleic acids selected for binding through the well known Selex method), and antibodies including antibody fragments. In certain embodiments wherein the biological marker of interest consists of an enzyme, these detection and quantification methods may also include detection and quantification of the corresponding enzyme activity.

Noticeably, antibodies are presently already available for most, if not all, the biological markers described in the present specification, including those biological markers that are listed in Table 4

Further, in situations wherein no antibody is yet available for a given biological marker, or in situations wherein the production of further antibodies to a given biological marker is sought, then antibodies directed against the said given biological markers may be easily obtained with the conventional techniques, including generation of antibody-producing hybridomas. In this method, a protein or peptide comprising the entirety or a segment of a biological marker protein is synthesised or isolated (e.g. by purification from a cell in which it is expressed or by transcription and translation of a nucleic acid encoding the protein or peptide in vivo or in vitro using known methods). A vertebrate, preferably a mammal such as a mouse, rat, rabbit, or sheep, is immunised using the protein or peptide. The vertebrate may optionally (and preferably) be immunised at least one additional time with the protein or peptide, so that the vertebrate exhibits a robust immune response to the protein or peptide. Splenocytes are isolated from the immunised vertebrate and fused with an immortalised cell line to form hybridomas, using any of a variety of methods well known in the art. Hybridomas formed in this manner are then screened using standard methods to identify one or more hybridomas which produce an antibody which specifically binds with the biological marker protein or a fragment thereof. The invention also encompasses hybridomas made by this method and antibodies made using such hybridomas. Polyclonal antibodies may be used as well.

Expression of a tissue-specific biological marker described herein may be assessed by any one of a wide variety of well known methods for detecting expression of a transcribed nucleic acid or protein. Non-limiting examples of such methods include immunological methods for detection of secreted, cell-surface, cytoplasmic, or nuclear proteins, protein purification methods, protein function or activity assays, nucleic acid hybridisation methods, nucleic acid reverse transcription methods, and nucleic acid amplification methods.

In one preferred embodiment, expression of a marker is assessed using an antibody (e.g. a radio-labelled, chromophore-labelled, fluorophore-labeled, polymer-backbone-antibody, or enzyme-labelled antibody), an antibody derivative (e.g. an antibody conjugated with a substrate or with the protein or ligand of a protein-ligand pair {e.g. biotin-streptavidin}), or an antibody fragment (e.g. a single-chain antibody, an isolated antibody hypervariable domain, etc.) which binds specifically with a marker protein or fragment thereof, including a marker protein which has undergone all or a portion of its normal post-translational modification.

In another preferred embodiment, expression of a marker is assessed by preparing mRNA/cDNA (i.e. a transcribed polynucleotide) from cells in a patient tumour tissue sample, and by hybridising the mRNA/cDNA with a reference polynucleotide which is a complement of a marker nucleic acid, or a fragment thereof. cDNA can, optionally, be amplified using any of a variety of polymerase chain reaction methods prior to hybridisation with the reference polynucleotide.

In a preferred embodiment of the in vitro prediction method according to the invention, step b) of detection and/or quantification of the one or more biological markers is performed using DNA microarrays. Illustratively, according to this preferred embodiment, a mixture of transcribed polynucleotides obtained from the sample is contacted with a substrate having fixed thereto a polynucleotide complementary to or homologous with at least a portion (e.g. at least 7, 10, 15, 20, 25, 30, 40, 50, 100, 500, or more nucleotide residues) of a biological marker nucleic acid. If polynucleotides complementary to or homologous with are differentially detectable on the substrate (e.g. detectable using different chromophores or fluorophores, or fixed to different selected positions), then the levels of expression of a plurality of markers can be assessed simultaneously using a single substrate (e.g. a “gene chip” microarray of polynucleotides fixed at selected positions). When a method of assessing marker expression is used which involves hybridisation of one nucleic acid with another, it is preferred that the hybridisation be performed under stringent hybridisation conditions.

An exemplary method for detecting and/or quantifying a biological marker protein or nucleic acid in a tumour tissue sample involves obtaining a tumour tissue sample. Said method includes further steps of contacting the biological sample with a compound or an agent capable of detecting the polypeptide or nucleic acid (e.g., mRNA or cDNA). The detection methods of the invention can thus be used to detect mRNA, protein, or cDNA, for example, in a tumour tissue sample in vitro. For example, in vitro techniques for detection of mRNA include Northern hybridisation and in situ hybridisation. In vitro techniques for detection of a biological marker protein include enzyme linked immunosorbent assays (ELISAs), Western blots, immunoprecipitations, immunofluorescence, and RT-PCR. A general principle of such detection and/or quantification assays involves preparing a sample or reaction mixture that may contain a biological marker, and a probe, under appropriate conditions and for a time sufficient to allow the marker and probe to interact and bind, thus forming a complex that can be removed and/or detected in the reaction mixture.

As used herein, the term “probe” refers to any molecule which is capable of selectively binding to a specifically intended target molecule, for example, a nucleotide transcript or protein encoded by or corresponding to a biological marker. Probes can be either synthesised by one skilled in the art, or derived from appropriate biological preparations. For purposes of detection of the target molecule, probes may be specifically designed to be labelled, as described herein. Examples of molecules that can be utilised as probes include, but are not limited to, RNA, DNA, proteins, antibodies, and organic molecules.

These detection and/or quantification assays of a biological marker can be conducted in a variety of ways.

For example, one method to conduct such an assay would involve anchoring the probe onto a solid phase support, also referred to as a substrate, and detecting target marker/probe complexes anchored on the solid phase at the end of the reaction. In one embodiment of such a method, a sample from a subject, which is to be assayed for quantification of the biological marker, can be anchored onto a carrier or solid phase support. In another embodiment, the reverse situation is possible, in which the probe can be anchored to a solid phase and a sample from a subject can be allowed to react as an unanchored component of the assay.

There are many established methods for anchoring assay components to a solid phase. These include, without limitation, marker or probe molecules which are immobilised through conjugation of biotin and streptavidin. Such biotinylated assay components can be prepared from biotin-NHS (N-hydroxy-succinimide) using techniques known in the art (e.g., biotinylation kit, Pierce Chemicals, Rockford, Ill.), and immobilised in the wells of streptavidin-coated 96 well plates (Pierce Chemical). In certain embodiments, the surfaces with immobilised assay components can be prepared in advance and stored.

Other suitable carriers or solid phase supports for such assays include any material capable of binding the class of molecule to which the marker or probe belongs. Well-known supports or carriers include, but are not limited to, glass, polystyrene, nylon, polypropylene, nylon, polyethylene, dextran, amylases, natural and modified celluloses, polyacrylamides, gabbros, and magnetite.

In order to conduct assays with the above mentioned approaches, the non-immobilised component is added to the solid phase upon which the second component is anchored. After the reaction is complete, uncomplexed components may be removed (e.g., by washing) under conditions such that any complexes formed will remain immobilised upon the solid phase. The detection of marker/probe complexes anchored to the solid phase can be accomplished in a number of methods outlined herein.

In a preferred embodiment, the probe, when it is the unanchored assay component, can be labelled for the purpose of detection and readout of the assay, either directly or indirectly, with detectable labels discussed herein and which are well-known to one skilled in the art.

It is also possible to directly detect marker/probe complex formation without further manipulation or labelling of either component (marker or probe), for example by utilising the technique of fluorescence energy transfer (see, for example, Lakowicz et al., U.S. Pat. No. 5,631,169; Stavrianopoulos, et al., U.S. Pat. No. 4,868,103). A fluorophore label on the first, ‘donor’ molecule is selected such that, upon excitation with incident light of appropriate wavelength, its emitted fluorescent energy will be absorbed by a fluorescent label on a second ‘acceptor’ molecule, which in turn is able to fluoresce due to the absorbed energy. Alternately, the ‘donor’ protein molecule may simply utilize the natural fluorescent energy of tryptophan residues. Labels are chosen that emit different wavelengths of light, such that the ‘acceptor’ molecule label may be differentiated from that of the ‘donor’. Since the efficiency of energy transfer between the labels is related to the distance separating the molecules, spatial relationships between the molecules can be assessed. In a situation in which binding occurs between the molecules, the fluorescent emission of the ‘acceptor’ molecule label in the assay should be maximal. A FRET binding event can be conveniently measured through standard fluorometric detection means well known in the art (e.g., using a fluorimeter).

In another embodiment, determination of the ability of a probe to recognise a marker can be accomplished without labelling either assay component (probe or marker) by utilising a technology such as real-time Biomolecular Interaction Analysis (BIA) (see, e.g., Sjolander, S. and Urbaniczky, C., 1991, Anal. Chem. 63:2338-2345 and Szabo et al., 1995, Curr. Opin. Struct. Biol. 5:699-705). As used herein, “BIA” or “surface plasmon resonance” is a technology for studying biospecific interactions in real time, without labelling any of the interactants (e.g., BIAcore). Changes in the mass at the binding surface (indicative of a binding event) result in alterations of the refractive index of light near the surface (the optical phenomenon of surface plasmon resonance (SPR)), resulting in a detectable signal which can be used as an indication of real-time reactions between biological molecules.

Alternatively, in another embodiment, analogous diagnostic and prognostic assays can be conducted with marker and probe as solutes in a liquid phase. In such an assay, the complexed marker and probe are separated from uncomplexed components by any of a number of standard techniques, including but not limited to: differential centrifugation, chromatography, electrophoresis and immunoprecipitation. In differential centrifugation, marker/probe complexes may be separated from uncomplexed assay components through a series of centrifugal steps, due to the different sedimentation equilibria of complexes based on their different sizes and densities (see, for example, Rivas, G., and Minton, A. P., 1993, Trends Biochem Sci. 18(8):284-7). Standard chromatographic techniques may also be utilized to separate complexed molecules from uncomplexed ones. For example, gel filtration chromatography separates molecules based on size, and through the utilization of an appropriate gel filtration resin in a column format, for example, the relatively larger complex may be separated from the relatively smaller uncomplexed components. Similarly, the relatively different charge properties of the marker/probe complex as compared to the uncomplexed components may be exploited to differentiate the complex from uncomplexed components, for example through the utilization of ion-exchange chromatography resins. Such resins and chromatographic techniques are well known to one skilled in the art (see, e.g., Heegaard, N. H., 1998, J. Mol. Recognit. Winter 11(1-6):141-8; Hage, D. S., and Tweed, S. A. J Chromatogr B Biomed Sci Appl 1997 Oct. 10; 699(1-2):499-525). Gel electrophoresis may also be employed to separate complexed assay components from unbound components (see, e.g., Ausubel et al., ed., Current Protocols in Molecular Biology, John Wiley & Sons, New York, 1987-1999). In this technique, protein or nucleic acid complexes are separated based on size or charge, for example. In order to maintain the binding interaction during the electrophoretic process, non-denaturing gel matrix materials and conditions in the absence of reducing agent are typically preferred. SELDI-TOF technique may also be employed on matrix or beads coupled with active surface, or not, or antibody coated surface, or beads.

Appropriate conditions to the particular assay and components thereof will be well known to one skilled in the art.

In a particular embodiment, the level of marker mRNA can be determined both by in situ and by in vitro formats in a biological sample using methods known in the art. The term “biological sample” is intended to include tissues, cells, biological fluids and isolates thereof, isolated from a subject, as well as tissues, cells and fluids present within a subject, provided that the said biological sample is susceptible to contain (i) cells originating from the breast cancer or (ii) nucleic acids or proteins that are produced by the breast cancer cells from the patient. Many expression detection methods use isolated RNA. For in vitro methods, any RNA isolation technique that does not select against the isolation of mRNA can be utilised for the purification of RNA from breast cancer (see, e.g., Ausubel et al., ed., Current Protocols in Molecular Biology, John Wiley & Sons, New York 1987-1999). Additionally, large numbers of tissue samples can readily be processed using techniques well known to those of skill in the art, such as, for example, the single-step RNA isolation process of Chomczynski (1989, U.S. Pat. No. 4,843,155).

The isolated mRNA can be used in hybridisation or amplification assays that include, but are not limited to, Southern or Northern analyses, polymerase chain reaction analyses and probe arrays. One preferred diagnostic method for the detection of mRNA levels involves contacting the isolated mRNA with a nucleic acid molecule (probe) that can hybridise to the mRNA encoded by the gene being detected. The nucleic acid probe can be, for example, a full-length cDNA, or a portion thereof, such as an oligonucleotide of at least 7, 15, 30, 50, 100, 250 or 500 nucleotides in length and sufficient to specifically hybridise under stringent conditions to a mRNA encoding a marker of the present invention. Other suitable probes for use in the pronostic assays of the invention are described herein. Hybridisation of an mRNA with the probe indicates that the marker in question is being expressed.

In most preferred embodiments of step b) of the in vitro prediction method according to the invention, detection and/or quantification of the metastasis-specific biological markers is performed by using suitable DNA microarrays. In such a marker detection/quantification format, the mRNA is immobilised on a solid surface and contacted with a probe, for example by running the isolated mRNA on an agarose gel and transferring the mRNA from the gel to a membrane, such as nitrocellulose. In an alternative format, the probe(s) are immobilized on a solid surface and the mRNA is contacted with the probe(s), for example, in an Affymetrix gene chip array. A skilled artisan can readily adapt known mRNA detection methods for use in detecting the level of mRNA encoded by the markers of the present invention. Specific hybridization technology which may be practiced to generate the expression profiles employed in the subject methods includes the technology described in U.S. Pat. Nos. 5,143,854; 5,288,644; 5,324,633; 5,432,049; 5,470,710; 5,492,806; 5,503,980; 5,510,270; 5,525,464; 5,547,839; 5,580,732; 5,661,028; 5,800,992; the disclosures of which are herein incorporated by reference; as well as WO 95/21265; WO 96/31622; WO 97/10365; WO 97/27317; EP 373 203; and EP 785 280. In these methods, an array of “probe” nucleic acids that includes a probe for each of the phenotype determinative genes whose expression is being assayed is contacted with target nucleic acids as described above. Contact is carried out under hybridization conditions, e.g., stringent hybridization conditions as described above, and unbound nucleic acid is then removed. The resultant pattern of hybridized nucleic acid provides information regarding expression for each of the genes that have been probed, where the expression information is in terms of whether or not the gene is expressed and, typically, at what level, where the expression data, i.e., expression profile, may be both qualitative and quantitative.

An alternative method for determining the level of mRNA marker in a sample involves the process of nucleic acid amplification, e.g., by rtPCR (the experimental embodiment set forth in Mullis, 1987, U.S. Pat. No. 4,683,202), ligase chain reaction (Barany, 1991, Proc. Natl. Acad. Sci. USA, 88:189-193), self sustained sequence replication (Guatelli et al., 1990, Proc. Natl. Acad. Sci. USA 87:1874-1878), transcriptional amplification system (Kwoh et al., 1989, Proc. Natl. Acad. Sci. USA 86:1173-1177), Q-Beta Replicase (Lizardi et al., 1988, Bio/Technology 6:1197), rolling circle replication (Lizardi et al., U.S. Pat. No. 5,854,033) or any other nucleic acid amplification method, followed by the detection of the amplified molecules using techniques well known to those of skill in the art. These detection schemes are especially useful for the detection of nucleic acid molecules if such molecules are present in very low numbers. As used herein, amplification primers are defined as being a pair of nucleic acid molecules that can anneal to 5′ or 3′ regions of a gene (plus and minus strands, respectively, or vice-versa) and contain a short region in between. In general, amplification primers are from about 10 to 30 nucleotides in length and flank a region from about 50 to 200 nucleotides in length. Under appropriate conditions and with appropriate reagents, such primers permit the amplification of a nucleic acid molecule comprising the nucleotide sequence flanked by the primers.

For in situ methods, mRNA does not need to be isolated from the breast cancer prior to detection. In such methods, a cell or tissue sample is prepared/processed using known histological methods. The sample is then immobilised on a support, typically a glass slide, and then contacted with a probe that can hybridise to mRNA that encodes the marker.

As an alternative to making determinations based on the absolute expression level of the marker, determinations may be based on the normalised expression level of the marker. Expression levels are normalised by correcting the absolute expression level of a marker by comparing its expression to the expression of a gene that is not a marker, e.g., a housekeeping gene that is constitutively expressed. Suitable genes for normalisation include housekeeping genes such as the actin gene, ribosomal 18S gene, GAPDH gene and TATA-box-binding protein (TBP). This normalisation allows the comparison of the expression level of one or more tissue-specific biological marker of interest in one sample.

Alternatively, the expression level can be provided as a relative expression level. To determine a relative expression level of a marker, the level of expression of the marker is determined for 10 or more samples of normal versus cancer cell isolates, preferably 50 or more samples, prior to the determination of the expression level for the sample in question. The median expression level of each of the genes assayed in the larger number of samples is determined and this is used as a baseline expression level for the marker. The expression level of the marker determined for the test sample (absolute level of expression) is then divided by the mean expression value obtained for that marker. This provides a relative expression level.

As already mentioned previously in the present specification, the detection/quantification reagent for detecting and/or quantifying a biological marker protein when performing the metastasis prediction method of the invention may consist of an antibody that specifically bind to such a biological marker protein or a fragment thereof, preferably an antibody with a detectable label. Antibodies can be polyclonal, or more preferably, monoclonal. An intact antibody, or a fragment or derivative thereof (e.g., Fab or F(ab').sub.2) can be used. The term “labelled”, with regard to the probe or antibody, is intended to encompass direct labelling of the probe or antibody by coupling (i.e., physically linking) a detectable substance to the probe or antibody, as well as indirect labelling of the probe or antibody by reactivity with another reagent that is directly labelled. Examples of indirect labelling include detection of a primary antibody using a fluorescently labelled secondary antibody and end-labelling of a DNA probe with biotin such that it can be detected with fluorescently labelled streptavidin.

One skilled in the art will know many other suitable carriers for binding antibody or antigen, and will be able to adapt such support for use with the present invention. For example, protein isolated from breast cancer can be run on a polyacrylamide gel electrophoresis and immobilised onto a solid phase support such as nitrocellulose. The support can then be washed with suitable buffers followed by treatment with the detectably labeled antibody. The solid phase support can then be washed with the buffer a second time to remove unbound antibody. The amount of bound label on the solid support can then be detected by conventional means.

The most preferred methods for quantifying a biological marker for the purpose of carrying out the metastasis prediction method of the invention are described hereunder.

Quantifying Biological Markers by cDNA Microarrays

According to this embodiment, a microarray may be constructed based on the metastasis-specific markers that are disclosed throughout the present specification. Metastasis-specific detection reagents including these markers may be placed on the microarray. These cancer metastasis-specific detection reagents may be different than those used in PCR methods. However, they should be designed and used in conditions such that only nucleic acids having the metastasis-specific marker may hybridize and give a positive result.

Most existing microarrays, such as those provided by Affymetrix (California), may be used with the present invention.

One of skill in the art will appreciate that an enormous number of array designs are suitable. The high density array will typically include a number of probes that specifically hybridize to the sequences of interest. See WO 99/32660 for methods of producing probes for a given gene or genes. In a preferred embodiment, the array will include one or more control probes.

Nucleic Acid Probes Immobilized on the Microarray Devices

High density array chips include <<test probes>> that specifically hybridize with mRNAs or cDNAs consisting of the products of expression of the meatstasis-specific biological markers that are described herein.

Test probes may be oligonucleotides that range from about 5 to about 500 or about 5 to about 200 nucleotides, more preferably from about 10 to about 100 nucleotides and most preferably from about 15 to about 70 nucleotides in length. In other particularly preferred embodiments, the probes are about 20 or 25 nucleotides in length. In another preferred embodiment, test probes are double or single strand DNA sequences. DNA sequences may be isolated or cloned from natural sources or amplified from natural sources using natural nucleic acid as templates. These probes have sequences complementary to particular subsequences of the metastasis-specific markers whose expression they are designed to detect.

In addition to test probes that bind the target nucleic acid(s) of interest, the high density array can contain a number of control probes. The control probes fall into three categories referred to herein as normalization controls; expression level controls; and mismatch controls. Normalization controls are oligonucleotide or other nucleic acid probes that are complementary to labeled reference oligonucleotides or other nucleic acid sequences that are added to the nucleic acid sample. The signals obtained from the normalization controls after hybridization provide a control for variations in hybridization conditions, label intensity, “reading” efficiency and other factors that may cause the signal of a perfect hybridization to vary between arrays. In a preferred embodiment, signals (e.g. fluorescence intensity) read from all other probes in the array are divided by the signal (, fluorescence intensity) from the control probes thereby normalizing the measurements. Virtually any probe may serve as a normalization control. However, it is recognized that hybridization efficiency varies with base composition and probe length. Preferred normalization probes are selected to reflect the average length of the other probes present in the array; however, they can be selected to cover a range of lengths. The normalization control(s) can also be selected to reflect the (average) base composition of the other probes in the array, however in a preferred embodiment, only one or a few probes are used and they are selected such that they hybridize well (i.e., no secondary structure) and do not match any target-specific probes. Expression level controls are probes that hybridize specifically with constitutively expressed genes in the biological sample. Virtually any constitutively expressed gene provides a suitable target for expression level controls. Typical expression level control probes have sequences complementary to subsequences of constitutively expressed “housekeeping genes” including the .beta.-actin gene, the transferrin receptor gene, and the GAPDH gene. Mismatch controls may also be provided for the probes to the target genes, for expression level controls or for normalization controls. Mismatch controls are oligonucleotide probes or other nucleic acid probes identical to their corresponding test or control probes except for the presence of one or more mismatched bases. A mismatched base is a base selected so that it is not complementary to the corresponding base in the target sequence to which the probe would otherwise specifically hybridize. One or more mismatches are selected such that under appropriate hybridization conditions (e.g., stringent conditions) the test or control probe would be expected to hybridize with its target sequence, but the mismatch probe would not hybridize (or would hybridize to a significantly lesser extent). Preferred mismatch probes contain a central mismatch. Thus, for example, where a probe is a twenty-mer, a corresponding mismatch probe may have the identical sequence except for a single base mismatch (e.g., substituting a G, a C or a T for an A) at any of positions 6 through 14 (the central mismatch). Mismatch probes thus provide a control for non-specific binding or cross hybridization to a nucleic acid in the sample other than the target to which the probe is directed. Mismatch probes also indicate whether hybridization is specific or not.

Solid Supports for DNA Microarrays

Solid supports containing oligonucleotide probes for differentially expressed genes can be any solid or semisolid support material known to those skilled in the art. Suitable examples include, but are not limited to, membranes, filters, tissue culture dishes, polyvinyl chloride dishes, beads, test strips, silicon or glass based chips and the like. Suitable glass wafers and hybridization methods are widely available. Any solid surface to which oligonucleotides can be bound, either directly or indirectly, either covalently or non-covalently, can be used. In some embodiments, it may be desirable to attach some oligonucleotides covalently and others non-covalently to the same solid support. A preferred solid support is a high density array or DNA chip. These contain a particular oligonucleotide probe in a predetermined location on the array. Each predetermined location may contain more than one molecule of the probe, but each molecule within the predetermined location has an identical sequence. Such predetermined locations are termed features. There may be, for example, from 2, 10, 100, 1000 to 10,000, 100,000 or 400,000 of such features on a single solid support. The solid support or the area within which the probes are attached may be on the order of a square centimeter. Methods of forming high density arrays of oligonucleotides with a minimal number of synthetic steps are known. The oligonucleotide analogue array can be synthesized on a solid substrate by a variety of methods, including, but not limited to, light-directed chemical coupling, and mechanically directed coupling (see U.S. Pat. No. 5,143,854 to Pirrung et al.; U.S. Pat. No. 5,800,992 to Fodor et al.; U.S. Pat. No. 5,837,832 to Chee et al.

In brief, the light-directed combinatorial synthesis of oligonucleotide arrays on a glass surface proceeds using automated phosphoramidite chemistry and chip masking techniques. In one specific implementation, a glass surface is derivatized with a silane reagent containing a functional group, e.g., a hydroxyl or amine group blocked by a photolabile protecting group. Photolysis through a photolithographic mask is used selectively to expose functional groups which are then ready to react with incoming 5′ photoprotected nucleoside phosphoramidites. The phosphoramidites react only with those sites which are illuminated (and thus exposed by removal of the photolabile blocking group). Thus, the phosphoramidites only add to those areas selectively exposed from the preceding step. These steps are repeated until the desired array of sequences has been synthesized on the solid surface. Combinatorial synthesis of different oligonucleotide analogues at different locations on the array is determined by the pattern of illumination during synthesis and the order of addition of coupling reagents.

In addition to the foregoing, methods which can be used to generate an array of oligonucleotides on a single substrate are described in WO 93/09668 to Fodor et al. High density nucleic acid arrays can also be fabricated by depositing premade or natural nucleic acids in predetermined positions. Synthesized or natural nucleic acids are deposited on specific locations of a substrate by light directed targeting and oligonucleotide directed targeting. Another embodiment uses a dispenser that moves from region to region to deposit nucleic acids in specific spots.

Oligonucleotide probe arrays for expression monitoring can be made and used according to any techniques known in the art (see for example, Lockhart et al., Nat. Biotechnol. 14, 1675-1680 (1996); McGall et al., Proc. Nat. Acad. Sci. USA 93, 13555-13460 (1996). Such probe arrays may contain at least two or more oligonucleotides that are complementary to or hybridize to two or more of the genes described herein. Such arrays may also contain oligonucleotides that are complementary to or hybridize to at least 3, 4, 5, 6, 7, 8, 9, 10, 20, 30, 50, 70 or more of the genes described therein.

Gene Signature Differential Analysis.

Gene Signature Differential analysis is a method designed to detect nucleic acids, like mRNAs or cDNAs differentially expressed in different samples.

Hybridization

Nucleic acid hybridization simply involves contacting a probe and target nucleic acid under conditions where the probe and its complementary target can form stable hybrid duplexes through complementary base pairing (see WO 99/32660 to Lockhart). The nucleic acids that do not form hybrid duplexes are then washed away leaving the hybridized nucleic acids to be detected, typically through detection of an attached detectable label. It is generally recognized that nucleic acids are denatured by increasing the temperature or decreasing the salt concentration of the buffer containing the nucleic acids. Under low stringency conditions (e.g., low temperature and/or high salt) hybrid duplexes (e.g., DNA-DNA, RNA-RNA or RNA-DNA) will form even where the annealed sequences are not perfectly complementary. Thus, specificity of hybridization is reduced at lower stringency. Conversely, at higher stringency (e.g., higher temperature or lower salt) successful hybridization requires fewer mismatches. One of skill in the art will appreciate that hybridization conditions may be selected to provide any degree of stringency. In a preferred embodiment, hybridization is performed at low stringency, in this case in 6.times.SSPE-T at 37.degree. C. (0.005% Triton x-100) to ensure hybridization and then subsequent washes are performed at higher stringency (e.g., 1.times.SSPE-T at 37.degree. C.) to eliminate mismatched hybrid duplexes. Successive washes may be performed at increasingly higher stringency (e.g. down to as low as 0.25.times.SSPE-T at 37.degree. C. to 50.degree. C.) until a desired level of hybridization specificity is obtained. Stringency can also be increased by addition of agents such as formamide. Hybridization specificity may be evaluated by comparison of hybridization to the test probes with hybridization to the various controls that can be present (e.g., expression level controls, normalization controls, mismatch controls, etc.).

In general, there is a tradeoff between hybridization specificity (stringency) and signal intensity. Thus, in a preferred embodiment, the wash is performed at the highest stringency that produces consistent results and that provides a signal intensity greater than approximately 10% of the background intensity. The hybridized array may be washed at successively higher stringency solutions and read between each wash. Analysis of the data sets thus produced will reveal a wash stringency above which the hybridization pattern is not appreciably altered and which provides adequate signal for the particular oligonucleotide probes of interest.

Signal Detection

The hybridized nucleic acids are typically detected by detecting one or more labels attached to the sample nucleic acids. The labels may be incorporated by any of a number of means well known to those of skill in the art (see WO 99/32660 to Lockhart). Any suitable methods can be used to detect one or more of the markers described herein. For example, gas phase ion spectrometry can be used. This technique includes, e.g., laser desorption/ionization mass spectrometry. In some embodiments, the sample can be prepared prior to gas phase ion spectrometry, e.g., pre-fractionation, two-dimensional gel chromatography, high performance liquid chromatography, etc. to assist detection of markers.

Quantifying Biological Markers by Immunohistochemistry on Conventional Tissue Slides (Paraffin-Embedded or Frozen Specimens)

In certain embodiments, a biological marker, or a set of biological markers, may be quantified with any one of the immunohistochemistry methods known in the art.

Typically, for further analysis, one thin section of the tumour, is firstly incubated with labelled antibodies directed against one biological marker of interest. After washing, the labelled antibodies that are bound to said biological marker of interest are revealed by the appropriate technique, depending of the kind of label, e.g. radioactive, fluorescent or enzyme label. Multiple labelling can be performed simultaneously.

Quantifying Biological Markers by Nucleic Acid Amplification

In certain embodiments, a biological marker, or a set of biological markers, may be quantified with any one of the nucleic acid amplification methods known in the art.

The polymerase chain reaction (PCR) is a highly sensitive- and powerful method for such biological markers quantification

For performing any one of the nucleic acid amplification method that is appropriate for quantifying a biological marker when performing the metastasis prediction method of the invention, a pair of primers that specifically hybridise with the target mRNA or with the target cDNA is required.

A pair of primers that specifically hybridise with the target nucleic acid biological marker of interest may be designed by any one of the numerous methods known in the art.

In certain embodiments, for each of the biological markers of the invention, at least one pair of specific primers, as well as the corresponding detection nucleic acid probe, is already referenced and entirely described in the public “Quantitative PCR primer database”, notably at the following Internet address: http://lpgws.nci.nih.gov/cgi-bin/PrimerViewer.

In other embodiments, a specific pair of primers may be designed using the method disclosed in the U.S. Pat. No. 6,892,141 to Nakae et al., the entire disclosure of which is herein incorporated by reference.

Many specific adaptations of the PCR technique are known in the art for both qualitative and quantitative detection purposes. In particular, methods are known to utilise fluorescent dyes for detecting and quantifying amplified PCR products. In situ amplification and detection, also known as homogenous PCR, have also been previously described. See e.g. Higuchi et al., (Kinetics PCR Analysis: Real-time Monitoring of DNA Amplification Reactions, Bio/Technology, Vol 11, pp 1026-1030 (1993)), Ishiguro et al., (Homogeneous quantitative Assay of Hepatitis C Virus RNA by Polymerase Chain Reaction in the Presence of a Fluorescent Intercalater, Anal. Biochemistry 229, pp 20-213 (1995)), and Wittwer et al., (Continuous Fluorescence Monitoring of Rapid cycle DNA Amplification, Biotechniques, vol. 22, pp 130-138 (1997.))

A number of other methods have also been developed to quantify nucleic acids (Southern, E. M., J. Mol. Biol., 98:503-517, 1975; Sharp, P. A., et al., Methods Enzymol. 65:750-768, 1980; Thomas, P. S., Proc. Nat. Acad. Sci., 77:5201-5205, 1980). More recently, PCR and RT-PCR methods have been developed which are capable of measuring the amount of a nucleic acid in a sample. One approach, for example, measures PCR product quantity in the log phase of the reaction before the formation of reaction products plateaus (Kellogg, D. E., et al., Anal. Biochem. 189:202-208 (1990); and Pang, S., et al., Nature 343:85-89 (1990)). A gene sequence contained in all samples at relatively constant quantity is typically utilised for sample amplification efficiency normalisation. This approach, however, suffers from several drawbacks. The method requires that each sample have equal input amounts of the nucleic acid and that the amplification efficiency between samples be identical until the time of analysis. Furthermore, it is difficult using the conventional methods of PCR quantitation such as gel electrophoresis or plate capture hybridisation to determine that all samples are in fact analysed during the log phase of the reaction as required by the method.

Another method called quantitative competitive (QC)-PCR, as the name implies, relies on the inclusion of an internal control competitor in each reaction (Becker-Andre, M., Meth. Mol. Cell Biol. 2:189-201 (1991); Piatak, M. J., et al., BioTechniques 14:70-81 (1993); and Piatak, M. J., et al., Science 259:1749-1754 (1993)). The efficiency of each reaction is normalised to the internal competitor. A known amount of internal competitor is typically added to each sample. The unknown target PCR product is compared with the known competitor PCR product to obtain relative quantitation. A difficulty with this general approach lies in developing an internal control that amplifies with the same efficiency of the target molecule.

For instance, the nucleic acid amplification method that is used may consist of Real-Time quantitative PCR analysis.

Real-time or quantitative PCR (QPCR) allows quantification of starting amounts of DNA, cDNA, or RNA templates. QPCR is based on the detection of a fluorescent reporter molecule that increases as PCR product accumulates with each cycle of amplification. Fluorescent reporter molecules include dyes that bind double-stranded DNA (i.e. SYBR Green I) or sequence-specific probes (i.e. Molecular Beacons or TaqMan® Probes).

Preferred nucleic acid amplification methods are quantitative PCR amplification methods, including multiplex quantitative PCR method such as the technique disclosed in the published US patent Application n^(o) US 2005/0089862, to Therianos et al., the entire disclosure of which is herein incorporated by reference.

Illustratively, for quantifying biological markers of the invention, tumor tissue samples are snap-frozen shortly after biopsy collection. Then, total RNA from a “tumour tissue sample” is isolated and quantified. Then, each sample of the extracted and quantified RNA is reverse-transcribed and the resulting cDNA is amplified by PCR, using a pair of specific primers for each biological marker that is quantified. Control pair of primers are simultaneously used as controls, such as pair of primers that specifically hybridise with TBP cDNA, 18S cDNA and GADPH cDNA, or any other well known “housekeeping” gene.

Illustrative embodiments of detection and quantification of the tissue-specific biological markers using nucleic acid amplification methods are disclosed in the examples herein.

The sequences of specific pairs of nucleic acid primers for detecting and/or quantifying various tissue-specific biological markers specified herein are expressly listed.

Further pairs of primers for detecting and/or quantifying the same tissue-specific biological markers are obtainable by the one skilled in the art, starting from the nucleic acid sequences of the said markers that are publicly available in the sequence databases.

Also, pairs of primers for the other tissue-specific markers disclosed herein are obtainable by the one skilled in the art, starting from the nucleic acid sequences of the said markers that are publicly available in the sequence databases.

Illustratively, specific pairs of primers that may be used for detecting and/or amplifying various tissue-specific biological markers are found below:

-   -   (i) bone metastasis-specific markers: KTCD1 (SEQ ID No 1 and 2),         BAIAP2L1 (SEQ ID No 3 and 4), PERP (SEQ ID No 5 and 6), CFD (SEQ         ID No 7 and 8), CD4 (SEQ ID No 9 and 10), COL6A2 (SEQ ID No 11         and 12), FLI1 (SEQ ID No 13 and 14), PSTPIP1 (SEQ ID No 15 and         16), MGF10 (SEQ ID No 17 and 18), PTPN22 (SEQ ID No 19 and 20),         FAM78A (SEQ ID No 21 and 22), NXF1 (SEQ ID No 23 and 24), MFNG         (SEQ ID No 25 and 26) and CLEC4A (SEQ ID No 27 and 28);     -   (ii) lung metastasis-specific markers: KIND1 (SEQ ID No 29 and         30), ELAC1 (SEQ ID No 31 and 32), ANP32E (SEQ ID No 33 and 34),         PAQR3 (SEQ ID No 35 and 36), ITGB8 (SEQ ID No 37 and 38),         c1orf210 (SEQ ID No 39 and 40), SIKE (SEQ ID No 41 and 42), UGT8         (SEQ ID No 43 and 44), CALB2

(SEQ ID No 45 and 46), CHODL (SEQ ID No 47 and 48), c21orf91 (SEQ ID No 49 and 50), TFCP2L1 (SEQ ID No 51 and 52), ODF2L (SEQ ID No 53 and 54), HORMAD1 (SEQ ID No 55 and 56), PLEKHG4 (SEQ ID No 57 and 58) and DSC2 (SEQ ID No 59 and 60);

-   -   (iii) liver metastasis-specific makers: GATA2 (SEQ ID No 61 and         62), SELT (SEQ ID No 63 and 64), WHSC1L1 (SEQ ID No 65 and 66),         MYRIP (SEQ ID No 67 and 68), ZMAT1 (SEQ ID No 69 and 70), IL20RA         (SEQ ID No 71 and 72), ZNF44 (SEQ ID No 73 and 74), LETM2 (SEQ         ID No 75 and 76), AGXT2L1 (SEQ ID No 77 and 78), c5orf30 (SEQ ID         No 79 and 80) and TBX3 (SEQ ID No 81 and 82).     -   (iv) brain metastasis-specific markers: PPWD1 (SEQ ID No 83 and         84), PDGFRA (SEQ ID No 85 and 86), MLL5 (SEQ ID No 87 and 88),         RPS23 (SEQ ID No 89 and 90), ANTXR1 (SEQ ID No 91 and 92),         ARRDC3 (SEQ ID No 93 and 94), METTL7A (SEQ ID No 95 and 96),         NPHP3 (SEQ ID No 97 and 98), RSHL1 (SEQ ID No 99 and 100), CSPP1         (SEQ ID No 101 and 102), HOXB13

(SEQ ID No 103 and 104), TRA16 (SEQ ID No 105 and 106), DDX27 (SEQ ID No 107 and 108), PKP2 (SEQ ID No 109 and 110) and INHA (SEQ ID No 111 and 112).

A pair of primers that may be used for quantifying the TATA-box Binding Protein (TBP) as a control consists of the nucleic acids of SEQ ID No 113-114 disclosed herein.

The primers having the nucleic acid sequences SEQ ID No 1 to SEQ ID No 114 are also described in Table 3 herein.

Kits for Predicting Metastasis in Breast Cancer

The invention also relates to a kit for the in vitro prediction of the occurrence of metastasis in one or more tissue or organ in a patient (e.g. in a tumour tissue sample previously collected from a breast cancer patient). The kit comprises a plurality of reagents, each of which is capable of binding specifically with a biological marker nucleic acid or protein.

Suitable reagents for binding with a marker protein include antibodies, antibody derivatives, antibody fragments, and the like.

Suitable reagents for binding with a marker nucleic acid (e.g. a genomic DNA, an mRNA, a spliced mRNA, a cDNA, or the like) include complementary nucleic acids. For example, the nucleic acid reagents may include oligonucleotides (labelled or non-labelled) fixed to a substrate, labelled oligonucleotides not bound with a substrate, pairs of PCR primers, molecular beacon probes, and the like.

Another object of the present invention consists of a kit for the in vitro prediction of the occurrence of metastasis in a patient, which kit comprises means for detecting and/or quantifying one or more biological markers that are indicative of an occurrence of metastasis in one or more tissue or organ, wherein the said one or more biological markers are selected from the group consisting of:

-   -   (i) one or more biological markers indicative of an occurrence         of metastasis in the bone tissue that are selected from the         group consisting of: CLEC4A, MFNG, NXF1, FAM78A, KCTD1,         BAIAP2L1, PTPN22, MEGF10, PERP, PSTPIP1, FLI1, COL6A2, CD4, CFD,         ZFHX1B, CD33, LST1, MMRN2, SH2D3C, RAMPS, FAM26B, ILK, TM6SF1,         C10orf54, CLEC3B, IL2RG, HOM-TES-103, ZNF23, STK35, TNFAIP8L2,         RAMP2, ENG, ACRBP, TBC1D10C, C11orf48, EBNA1BP2, HSPE1, GAS6,         HCK, SLC2A5, RASA3, ZNF57, WASPIP, KCNK1, GPSM3, ADCY4, AIF1,         NCKAP1, AMICA1, POP7, GMFG, PPM1M, CDGAP, GIMAP1, ARHGAP9,         APOB48R, OCIAD2, FLRT2, P2RY8, RIPK4, PECAM1, URP2, BTK,         APBB1IP, CD37, STARD8, GIMAP6, E2F6, WAS, HLA-DQB1, HVCN1,         L0056902, ORC5L, MEF2C, PLCL2, PLAC9, RAC2, SYNE1, DPEP2, MYEF2,         HSPD1, PSCD4, NXT1, LOC340061, ITGB3, AP1S2, SNRPG, CSF1, BIN2,         ANKRD47, LIMS2, DARC, PTPN7, MSH6, GGTA1, LRRC33, GDPD5,         CALC0001, FAM110C, BCL6B, LOC641700, ARHGDIB, DAAM2, TNFRSF14,         TPSAB1, CSF2RA, RCSD1, F1121438, LOC133874, GSN, SLIT3, FYN,         NCF4, PTPRC, EVI2B, SCRIB, C11orf31, LOC440731, TFAM, ARPC5L,         PARVG, GRN, LMO2, CRSP8, EHBP1L1, HEATR2, NAALADL1, INPP5D, LTB,         STRBP, FAM65A, ADARB1, TMEM140, DENND1C, PRPF19, CASP10SLC37A2,         RHOJ, MPHOSPH10, PPIH, RASSF1, HDST, C16orf54, EPB41L4B, LRMP,         LAPTM5, PRDM2, CYGB, LYCAT, ACP5, CMKLR1, UBE1L, MAN2C1,         TNFSF12, C7orf24, Cxorf15, CUL1, SMAD7, ITGB7, APOL3, PGRMC1,         PPA1, YES1, FBLN1, MRC2, PTK9L, LRP1, IGFBP5, WDR3, GTPBP4,         SPI1, SELPLG, OSCAR, LYL1, POLR2H, YWHAQ, ISG20L2, LGI14, KIF5B,         NGRN, TYROBP, C5orf4, COX7A2, S100A4, MATK, TMEM33, DOK3,         LOC150166, CIRBP, NIN, C10orf72, FMNL1, FATS, CHKB/CPT1B,         SNRPA1, GIMAP4, C20orf18, LTBP2, GABS, NQO1, MARCH2, MYO1F,         CDS1, SRD5A1, C20orf160, SLAMF7, ACTL6A, ABP1, RAE1, MAF,         SEMA3G, P2RY13, ZDHHC7, ERG, FHL1, CLEC10A, INTS5, MYO15B, CTSW,         PILRA, HN1, SCARA5, PRAM1, EBP, SIGLEC9, LGP1, DGUOK, GGCX,         RABL5, ZBTB16, TPSAB1, NOP5/NOP58, CCND2, CD200, EPPK1,         DKFZp586C0721, CCT6A, RIPK3, ARHGAP25, GNAI2, USP4, FAHD2A,         LOC399959, LOC133308, HKDC1, CD93, GTF3C4, ITGB2, ELOVL6,         TGFB111, ASCC3L1, FES, KCNMB1, AACS, ATP6VOD2, TMEM97, NUDT15,         ATP6V1B2, CCDC86, FLJ10154, SCARF2, PRELP, ACHE, GIMAP8,         PDE4DIP, NKG7, C20orf59, RHOG, TRPV2, TCP1, TNRC8, TNS1, IBSP,         MMP9, NRIP2, OLFML2B, OMD, WIF1, ZEB2, ARL8, COL12A1, EBF and         EBF3;     -   (ii) one or more biological markers indicative of an occurrence         of metastasis in the lung tissue that are selected from the         group consisting of: DSC2, HORMAD1, PLEKHG4, ODF2L, C21orf91,         TFCP2L1, TTMA, CHODL, CALB2, UGT8, LOC146795, C1orf210, SIKE,         ITGB8, PAQR3, ANP32E, C20orf42/FERMT1, ELAC1, GYLTL1B, SPSB1,         CHRM3, PTEN, PIGL, CHRM3, CDH3;     -   (iii) one or more biological markers indicative of an occurrence         of metastasis in the liver tissue that are selected from the         group consisting of: TBX3, SYT17, LOC90355, AGXT2L1, LETM2,         LOC145820, ZNF44, IL20RA, ZMAT1, MYRIP, WHSC1L1, SELT, GATA2,         ARPC2, CAB39L, SLCI6A3, DHFRL1, PRRT3, CYP3A5, RPS6KA5,         KIAA1505, ATP5S, ZFYVE16, KIAA0701, PEBP1, DDHD2, WWP1, CCNL1,         ROBO2, FAM111B, THRAP2, CRSP9, KARCA1, SLC16A3, ARID4A, TCEAL1,         SCAMP1, KIAAO701, EIF5A, DDX46, PEX7, BCL2L11, YBX1, UBE21,         REXO2, AXUD1, C10orf2, ZNF548, FBXL16, LOC439911, LOC283874,         ZNF587, FLJ20366, KIAAO888, BAG4, CALU, KIAA1961, USP30, NR4A2,         FOXA1, FBXO15, WNK4, CDIPT, NUDT16L1, SMAD5, STXBP4, TTC6,         LOC113386, TSPYL1, CIP29, C8orf1, SYDE2, SLC12A8, SLC25A18, C7,         STAU2, TSC22D2, GADD45G, PHF3, TNRC6C, TCEAL3, RRN3, C5orf24,         AHCTF1, LOC92497; and     -   (iv) one or more biological markers indicative of an occurrence         of metastasis in the brain tissue that are selected from the         group consisting of: LOC644215, BAT1, GPR75, PPWD1, INHA,         PDGFRA, MLL5, RPS23, ANTXR1, ARRDC3, PTK2, SQSTM1, METTL7A,         NPHP3, PKP2, DDX31, FAM119A, LLGL2, DDX27, TRA16, HOXB13, GNAS,         CSPP1, COL8A1, RSHL1, DCBLD2, UBXD8, SURF2, ZNF655, RAC3, AP4M1,         HEG1, PCBP2, SLC30A7, ATAD3A/ATAD3B, CHI3L1, MUC6, HMG20B,         BCL7A, GGN, ARHGEF3, PALLD, TOP1, PCTK1, C20orf4, ZBTB1, MSH6,         SETD5, POSTN, MOCS3, GABPA, ZSWIM1, ZNHIT2, LOC653352, ELL,         ARPC4, ZNF277, VAV2, HNRPH3, LHX1, FAM83A, DIP2B, RBM10, PMPCA,         TYSND1, RAB4B, DLC1, KIAA2018, TES, TFDP2, C3orf10, ZBTB38,         PSMD7, RECK, JMJD1C, F1120273, CENPB, PLAC2, C6orf111, ATP10D,         RNF146, XRRA1, NPAS2, APBA2BP, WDR34, SLK, SBF2, SON, MORC3,         C3orf63, WDR54, STX7, ZNF512, KLHL9, LOC284889, ETV4, RMND5B,         ARMCX1, SLC29A4, TRIB3, LRRC23, DDIT3, THUMPD3, MICAL-L2, PA2G4,         TSEN54, LAS1L, MEA1, S100PBP, TRAF2, EMILIN3, KIAA1712, PRPF6,         CHD9, JMJD1B, ANKS1A, CAPN5, EPC2, WBSCR27, CYB561, LLGL1, EDD1.

The present invention also encompasses various alternative embodiments of the said prediction kit, wherein the said prediction kit comprises combination of marker detection and/or marker quantification means, for detecting and/or quantifying various combinations of the markers described in the present specification.

In certain embodiments of the invention, the said prediction kit consists of a kit for the in vitro prediction of the occurrence of lung metastasis in a patient who is affected with a breast cancer, wherein the said kit comprises means for detecting and/or quantifying one or more biological markers that are indicative of an occurrence of metastasis in the lung tissue, wherein the said one or more biological markers are selected from the group consisting of DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.

In certain embodiments of the said prediction kit, it comprises means for detecting and/or quantifying 2, 3, 4, 5 or all of the following lung-specific markers: DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.

In further embodiments, the said prediction kit comprises means for detecting and/or quantifying the whole combination of the six following markers: DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.

In yet further embodiments, the said prediction kit comprises means for detecting and/or quantifying exclusively the whole combination of the six following markers: DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1, together with means for detecting and/or quantifying one or more reference markers, e.g. markers corresponding to ubiquitously expressed genes or proteins like actin.

Most preferably, a prediction kit according to the invention consists of a DNA microarray comprising probes hybridizing to the nucleic acid expression products (mRNAs or cDNAs) of the metastasis-specific biological markers described herein.

Another object of the present invention consists of a kit for monitoring the anti-metastasis effectiveness of a therapeutic treatment of a patient affected with a breast cancer with a pharmaceutical agent, which kit comprises means for quantifying one or more biological markers that are indicative of an occurrence of metastasis in one or more tissue or organ, wherein the said one or more biological markers are selected from the group consisting of:

-   -   (i) one or more biological markers indicative of an occurrence         of metastasis in the bone tissue that are selected from the         group consisting of: CLEC4A, MFNG, NXF1, FAM78A, KCTD1,         BAIAP2L1, PTPN22, MEGF10, PERP, PSTPIP1, FLI1, COL6A2, CD4, CFD,         ZFHX1B, CD33, LST1, MMRN2, SH2D3C, RAMP3, FAM26B, ILK, TM6SF1,         C10orf54, CLEC3B, IL2RG, HOM-TES-103, ZNF23, STK35, TNFAIP8L2,         RAMP2, ENG, ACRBP, TBC1D10C, C11orf48, EBNA1BP2, HSPE1, GAS6,         HCK, SLC2A5, RASA3, ZNF57, WASPIP, KCNK1, GPSM3, ADCY4, AIF1,         NCKAP1, AMICA1, POP7, GMFG, PPM1M, CDGAP, GIMAP1, ARHGAP9,         APOB48R, OCIAD2, FLRT2, P2RY8, RIPK4, PECAM1, URP2, BTK,         APBB1IP, CD37, STARD8, GIMAP6, E2F6, WAS, HLA-DQB1, HVCN1,         L0056902, ORC5L, MEF2C, PLCL2, PLAC9, RAC2, SYNE1, DPEP2, MYEF2,         HSPD1, PSCD4, NXT1, LOC340061, ITGB3, AP1S2, SNRPG, CSF1, BIN2,         ANKRD47, LIMS2, DARC, PTPN7, MSH6, GGTA1, LRRC33, GDPD5,         CALC0001, FAM110C, BCL6B, LOC641700, ARHGDIB, DAAM2, TNFRSF14,         TPSAB1, CSF2RA, RCSD1, F1121438, LOC133874, GSN, SLIT3, FYN,         NCF4, PTPRC, EVI2B, SCRIB, C11orf31, LOC440731, TFAM, ARPC5L,         PARVG, GRN, LMO2, CRSP8, EHBP1L1, HEATR2, NAALADL1, INPP5D, LTB,         STRBP, FAM65A, ADARB1, TMEM140, DENND1C, PRPF19, CASP10,         SLC37A2, RHOJ, MPHOSPH10, PPIH, RASSF1, HCST, C16orf54,         EPB41L4B, LRMP, LAPTM5, PRDM2, CYGB, LYCAT, ACP5, CMKLR1, UBE1L,         MAN2C1, TNFSF12, C7orf24, Cxorf15, CUL1, SMAD7, ITGB7, APOL3,         PGRMC1, PPA1, YES1, FBLN1, MRC2, PTK9L, LRP1, IGFBP5, WDR3,         GTPBP4, SPI1, SELPLG, OSCAR, LYL1, POLR2H, YWHAQ, ISG20L2,         LGI14, KIF5B, NGRN, TYROBP, C5orf4, COX7A2, S100A4, MATK,         TMEM33, DOK3, LOC150166, CIRBP, NIN, C10orf72, FMNL1, FATS,         CHKB/CPT1B, SNRPA1, GIMAP4, C20orf18, LTBP2, GABS, NQO1, MARCH2,         MYO1F, CDS1, SRD5A1, C20orf160, SLAMF7, ACTL6A, ABP1, RAE1, MAF,         SEMA3G, P2RY13, ZDHHC7, ERG, FHL1, CLEC10A, INTS5, MYO5B, CTSW,         PILRA, HN1, SCARA5, PRAM1, EBP, SIGLEC9, LGP1, DGUOK, GGCX,         RABL5, ZBTB16, TPSAB1, NOP5/NOP58, CCND2, CD200, EPPK1,         DKFZp586CO721, CCT6A, RIPK3, ARHGAP25, GNAI2, USP4, FAHD2A,         LOC399959, LOC133308, HKDC1, CD93, GTF3C4, ITGB2, ELOVL6,         TGFB111, ASCC3L1, FES, KCNMB1, AACS, ATP6VOD2, TMEM97, NUDT15,         ATP6V1B2, CCDC86, FLJ10154, SCARF2, PRELP, ACHE, GIMAP8,         PDE4DIP, NKG7, C20orf59, RHOG, TRPV2, TCP1, TNRC8, TNS1, IBSP,         MMP9, NRIP2, OLFML2B, OMD, WIF1, ZEB2, ARL8, COL12A1, EBF and         EBF3,     -   (ii) one or more biological markers indicative of an occurrence         of metastasis in the lung tissue that are selected from the         group consisting of: DSC2, HORMAD1, PLEKHG4, ODF2L, C21orf91,         TFCP2L1, TTMA, CHODL, CALB2, UGT8, LOC146795, C1orf210, SIKE,         ITGB8, PAQR3, ANP32E, C20orf42, ELAC1, GYLTL1B, SPSB1, CHRM3,         PTEN, PIGL, CHRM3, CDH3;     -   (iii) one or more biological markers indicative of an occurrence         of metastasis in the liver tissue that are selected from the         group consisting of: TBX3, SYT17, LOC90355, AGXT2L1, LETM2,         LOC145820, ZNF44, IL20RA, ZMAT1, MYRIP, WHSC1 L1, SELT, GATA2,         ARPC2, CAB39L, SLCI6A3, DHFRL1, PRRT3, CYP3A5, RPS6KA5,         KIAA1505, ATP5S, ZFYVE16, KIAA0701, PEBP1, DDHD2, WWP1, CCNL1,         ROBO2, FAM111B, THRAP2, CRSP9, KARCA1, SLC16A3, ARID4A, TCEAL1,         SCAMP1, KIAAO701, EIF5A, DDX46, PEX7, BCL2L11, YBX1, UBE21,         REXO2, AXUD1, C10orf2, ZNF548, FBXL16, LOC439911, LOC283874,         ZNF587, FLJ20366, KIAAO888, BAG4, CALU, KIAA1961, USP30, NR4A2,         FOXA1, FBXO15, WNK4, CDIPT, NUDT16L1, SMAD5, STXBP4, TTC6,         LOC113386, TSPYL1, CIP29, C8orf1, SYDE2, SLC12A8, SLC25A18, C7,         STAU2, TSC22D2, GADD45G, PHF3, TNRC6C, TCEAL3, RRN3, C5orf24,         AHCTF1, LOC92497; and     -   (iv) one or more biological markers indicative of an occurrence         of metastasis in the brain tissue that are selected from the         group consisting of: LOC644215, BAT1, GPR75, PPWD1, INHA,         PDGFRA, MLL5, RPS23, ANTXR1, ARRDC3, PTK2, SQSTM1, METTL7A,         NPHP3, PKP2, DDX31, FAM119A, LLGL2, DDX27, TRA16, HOXB13, GNAS,         CSPP1, COL8A1, RSHL1, DCBLD2, UBXD8, SURF2, ZNF655, RAC3, AP4M1,         HEG1, PCBP2, SLC30A7, ATAD3A/ATAD3B, CHI3L1, MUC6, HMG20B,         BCL7A, GGN, ARHGEF3, PALLD, TOP1, PCTK1, C20orf4, ZBTB1, MSH6,         SETD5, POSTN, MOCS3, GABPA, ZSWIM1, ZNHIT2, LOC653352, ELL,         ARPC4, ZNF277, VAV2, HNRPH3, LHX1, FAM83A, DIP2B, RBM10, PMPCA,         TYSND1, RAB4B, DLC1, KIAA2018, TES, TFDP2, C3orf10, ZBTB38,         PSMD7, RECK, JMJD1C, FLJ20273, CENPB, PLAC2, C6orf111, ATP10D,         RNF146, XRRA1, NPAS2, APBA2BP, WDR34, SLK, SBF2, SON, MORC3,         C3orf63, WDR54, STX7, ZNF512, KLHL9, LOC284889, ETV4, RMND5B,         ARMCX1, SLC29A4, TRIB3, LRRC23, DDIT3, THUMPD3, MICAL-L2, PA2G4,         TSEN54, LAS1L, MEA1, S100PBP, TRAF2, EMILIN3, KIAA1712, PRPF6,         CHD9, JMJD1B, ANKS1A, CAPN5, EPC2, WBSCR27, CYB561, LLGL1, EDD1.

The present invention also encompasses various alternative embodiments of the said monitoring kit, wherein the said monitoring kit comprises combination of marker detection and/or marker quantification means, for detecting and/or quantifying various combinations of the markers described in the present specification.

In certain embodiments of the invention, the said monitoring kit consists of a kit for the in vitro prediction of the occurrence of lung metastasis in a patient who is affected with a breast cancer, wherein the said kit comprises means for detecting and/or quantifying one or more biological markers that are indicative of an occurrence of metastasis in the lung tissue, wherein the said one or more biological markers are selected from the group consisting of DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.

In certain embodiments of the said monitoring kit, it comprises means for detecting and/or quantifying 2, 3, 4, 5 or all of the following lung-specific markers: DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.

In further embodiments, the said monitoring kit comprises means for detecting and/or quantifying the whole combination of the six following markers: DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.

In yet further embodiments, the said monitoring kit comprises means for detecting and/or quantifying exclusively the whole combination of the six following markers: DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1, together with means for detecting and/or quantifying one or more reference markers, e.g. markers corresponding to ubiquitously expressed genes or proteins like actin.

The prediction kit and the monitoring kit of the invention may optionally comprise additional components useful for performing the methods of the invention. By way of example, the kits may comprise fluids (e.g. SSC buffer) suitable for annealing complementary nucleic acids or for binding an antibody with a protein with which it specifically binds, one or more sample compartments, an instructional material which describes performance of the prediction method or of the monitoring method of the invention, and the like.

Kits Comprising Antibodies

In certain embodiments, a kit according to the invention comprises one or a combination or a set of antibodies, each kind of antibodies being directed specifically against one biological marker of the invention.

In one embodiment, said kit comprises a combination or a set of antibodies comprising at least two kind of antibodies, each kind of antibodies being selected from the group consisting of antibodies directed against one of the biological markers disclosed herein.

An antibody kit according to the invention may comprise 2 to 20 kinds of antibodies, each kind of antibodies being directed specifically against one biological marker of the invention. For instance, an antibody kit according to the invention may comprise 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19 or 20 kinds of antibodies, each kind of antibodies being directed specifically against one biological marker as defined herein.

Various antibodies directed against biological markers according to the invention encompass antibodies directed against biological markers selected from the group consisting of those metastasis-specific markers that are listed in Table 4. Specific embodiments of these antibodies are listed in Table 4 herein.

Specific embodiments of a prediction kit according to the invention which contains detection/quantification means consisting of antibodies include the fluorescent microsphere-bound antibody suspension array technology, e.g. the kit technology that is marketed under the trademark Bio-Plex® by the Bio-Rad Company.

Concurrent with the increasing interest in magnetic microspheres for biological assays is the development of assays conducted on fluorescent microspheres. The use of fluorescent labels or fluorescent material coupled to a surface of the microspheres or incorporated into the microspheres allows preparation of numerous sets of microspheres that are distinguishable based on different dye emission spectra and/or signal intensity. In a biological assay, the fluorescence and light scattering of these microspheres can be measured by a flow cytometer or an imaging system, and the measurement results can be used to determine the size and fluorescence of the microspheres as well as the fluorescence associated with the assay system being studied (e.g., a fluorescently labeled antibody in a “capture sandwich” assay), as described in U.S. Pat. No. 5,948,627 to Lee et al., which is incorporated by reference as if fully set forth herein. By varying the concentrations of multiple dyes incorporated in the microspheres, hundreds, or even thousands, of distinguishable microsphere sets can be produced. In an assay, each microsphere set can be associated with a different target thereby allowing numerous tests to be conducted for a single sample in a single container as described in U.S. Pat. No. 5,981,180 to Chandler et al., which is incorporated by reference as if fully set forth herein.

Fluorescently distinguishable microspheres may be improved by rendering these microspheres magnetically responsive. Examples of methods for forming fluorescent magnetic microspheres are described in U.S. Pat. No. 5,283,079 to Wang et al., which is incorporated by reference as if fully set forth herein. The methods described by Wang et al. include coating a fluorescent core microsphere with magnetite and additional polymer or mixing a core microsphere with magnetite, dye, and polymerizable monomers and initiating polymerization to produce a coated microsphere. These methods are relatively simple approaches to the synthesis of fluorescent magnetic microspheres.

Additionally, for creating a large numbers of precisely dyed microspheres used in relatively large multiplex assays, those as described in U.S. Pat. No. 5,981,180 to Chandler et al. may be used.

Fluorescent magnetic microspheres are also described in U.S. Pat. No. 6,268,222 to Chandler et al., which is incorporated by reference as if fully set forth herein. In this method, nanospheres are coupled to a polymeric core microsphere, and the fluorescent and magnetic materials are associated with either the core microsphere or the nanospheres. This method produces microspheres with desirable characteristics.

A further embodiment of fluorescent magnetic microspheres is a magnetically responsive microspheres that can be dyed using established techniques, such as those described in U.S. Pat. No. 6,514,295 to Chandler et al. In general, this method uses solvents that swell the microsphere thereby allowing migration of the fluorescent material into the microsphere. These dyeing solvents include one or more organic solvents.

Also, magnetic microspheres are described in U.S. Pat. No. 5,091,206 to Wang et al., U.S. Pat. No. 5,648,124 to Sutor, and U.S. Pat. No. 6,013,531 to Wang et al., which are incorporated by reference as if fully set forth herein.

In certain other embodiments, a kit according to the invention comprises one or a combination or a set of pair of ligands or specfic soluble molecules binding with one or more of the biological marker(s), of the invention.

Kits Comprising Nucleic Acid Primers

In certain other embodiments, a kit according to the invention comprises one or a combination or a set of pair of primers, each kind of pair of primers hybridising specifically with one biological marker of the invention.

In one embodiment, said kit comprises a combination or a set of pair of primers comprising at least two kind of pair of primers, each kind of pair of primers being selected from the group consisting of pair of primers hybridising with one of the biological markers disclosed in the present specification, including the pairs of primers of SEQ ID No 1-112 that are detailed earlier in the specification.

A primer kit according to the invention may comprise 2 to 20 kinds of pair or primers, each kind of pair of primers hybridising specifically with one biological marker of the invention. For instance, a primer kit according to the invention may comprise 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19 or 20 kinds of pairs of primers, each kind of pair of primers hybridising specifically against one biological marker as defined herein.

Notably, at least one pair of specific primers, as well as the corresponding detection nucleic acid probe, that hybridise specifically with one biological marker of interest, is already referenced and entirely described in the public “Quantitative PCR primer database”, notably at the following Internet address: http://lpgws.nci.nih.gov/cgi-bin/PrimerViewer.

Illustratively, a prediction kit or a monitoring kit according to the invention may comprise one or more specific pairs of primers for detecting and/or amplifying various tissue-specific biological markers, among the primers specified below:

-   -   (i) bone metastasis-specific markers: KTCD1 (SEQ ID No 1 and 2),         BAIAP2L1 (SEQ ID No 3 and 4), PERP (SEQ ID No 5 and 6), CFD (SEQ         ID No 7 and 8), CD4 (SEQ ID No 9 and 10), COL6A2 (SEQ ID No 11         and 12), FLI1 (SEQ ID No 13 and 14), PSTPIP1 (SEQ ID No 15 and         16), MGF10 (SEQ ID No 17 and 18), PTPN22 (SEQ ID No 19 and 20),         FAM78A (SEQ ID No 21 and 22), NXF1 (SEQ ID No 23 and 24), MFNG         (SEQ ID No 25 and 26) and CLEC4A (SEQ ID No 27 and 28);     -   (ii) lung metastasis-specific markers: KIND1 (SEQ ID No 29 and         30), ELAC1 (SEQ ID No 31 and 32), ANP32E (SEQ ID No 33 and 34),         PAQR3 (SEQ ID No 35 and 36), ITGB8 (SEQ ID No 37 and 38),         c1orf210 (SEQ ID No 39 and 40), SIKE (SEQ ID No 41 and 42), UGT8         (SEQ ID No 43 and 44), CALB2 (SEQ ID No 45 and 46), CHODL (SEQ         ID No 47 and 48), c21orf91 (SEQ ID No 49 and 50), TFCP2L1 (SEQ         ID No 51 and 52), ODF2L (SEQ ID No 53 and 54), HORMAD1 (SEQ ID         No 55 and 56), PLEKHG4 (SEQ ID No 57 and 58) and DSC2 (SEQ ID No         59 and 60);     -   (iii) liver metastasis-specific makers: GATA2 (SEQ ID No 61 and         62), SELT (SEQ ID No 63 and 64), WHSC1L1 (SEQ ID No 65 and 66),         MYRIP (SEQ ID No 67 and 68), ZMAT1 (SEQ ID No 69 and 70), IL20RA         (SEQ ID No 71 and 72), ZNF44 (SEQ ID No 73 and 74), LETM2 (SEQ         ID No 75 and 76), AGXT2L1 (SEQ ID No 77 and 78), c5orf30 (SEQ ID         No 79 and 80) and TBX3 (SEQ ID No 81 and 82).     -   (iv) brain metastasis-specific markers: PPWD1 (SEQ ID No 83 and         84), PDGFRA (SEQ ID No 85 and 86), MLL5 (SEQ ID No 87 and 88),         RPS23 (SEQ ID No 89 and 90), ANTXR1 (SEQ ID No 91 and 92),         ARRDC3 (SEQ ID No 93 and 94), METTL7A (SEQ ID No 95 and 96),         NPHP3 (SEQ ID No 97 and 98), RSHL1 (SEQ ID No 99 and 100), CSPP1         (SEQ ID No 101 and 102), HOXB13 (SEQ ID No 103 and 104), TRA16         (SEQ ID No 105 and 106), DDX27 (SEQ ID No 107 and 108), PKP2         (SEQ ID No 109 and 110) and INHA (SEQ ID No 111 and 112).

These kits may also comprise one or more pairs of primers for detecting and/or quantifying a control marker. Illustratively, these kits may comprise a pair of primer for detecting and/or quantifying the TATA-box Binding Protein (TBP), such as the nucleic acids of SEQ ID No 113-114 disclosed herein.

Monitoring Anti-Cancer Treatments

Monitoring the influence of agents (e.g., drug compounds) on the level of expression of one or more tissue-specific biological markers of the invention can be applied for monitoring the metastatic potency of the treated breast cancer of the patient with time. For example, the effectiveness of an agent to affect biological marker expression can be monitored during treatments of subjects receiving anti-cancer, and especially anti-metastasis, treatments.

In a preferred embodiment, the present invention provides a method for monitoring the effectiveness of treatment of a subject with an agent (e.g., an agonist, antagonist, peptidomimetic, protein, peptide, nucleic acid, small molecule, or other drug candidate) comprising the steps of (i) obtaining a pre-administration sample from a subject prior to administration of the agent; (ii) detecting the level of expression of one or more selected biological markers of the invention in the pre-administration sample; (iii) obtaining one or more post-administration samples from the subject; (iv) detecting the level of expression of the biological marker(s) in the post-administration samples; (v) comparing the level of expression of the biological marker(s) in the pre-administration sample with the level of expression of the marker(s) in the post-administration sample or samples; and (vi) altering the administration of the agent to the subject accordingly. For example, decreased expression of the biological marker gene(s) during the course of treatment may indicate ineffective dosage and the desirability of increasing the dosage. Conversely, increased expression of the biological marker gene(s) may indicate efficacious treatment and no need to change dosage.

Because repeated collection of biological samples from the breast cancer-bearing patient are needed for performing the monitoring method described above, then preferred biological samples consist of blood samples susceptible to contain (i) cells originating from the patient's breast cancer tissue, or (ii) metastasis-specific marker expression products synthesized by cells originating from the patients breast cancer tissue, including nucleic acids and proteins. As used herein, the said “breast cancer patient's tissue includes the primary tumor tissue as well as a organ-specific or tissue-specific metastasis tissue.

As already mentioned previously in the present specification, performing the metastasis prediction method of the invention may indicate, with more precision than the prior art methods, those patients at high-risk of tumor recurrence who may benefit from adjuvant therapy, including immunotherapy.

For example, if, at the end of the metastasis prediction method of the invention, a good prognosis of no metastasis is determined, then the subsequent anti-cancer treatment will not comprise any adjuvant chemotherapy.

However, if, at the end of the metastasis prediction method of the invention, a bad prognosis with is determined, then the patient is administered with the appropriate composition of adjuvant chemotherapy.

Accordingly, the present invention also relates to a method for adapting a cancer treatment in a breast cancer patient, wherein said method comprises the steps of:

-   -   a) performing, on at least one tumor tissue sample collected         from said patient, the metastasis prediction method that is         disclosed herein;     -   b) adapting the cancer treatment of the said cancer patient by         administering to the said patient an adjuvant chemotherapy or an         anti-metastasis therapy if a bad cancer prognosis with         metastasis in one or more tissue or organ, including bone, lung,         liver and brain, is determined at the end of step a).

Another object of the invention consists of a kit for monitoring the effectiveness of treatment (adjuvant or neo-adjuvant) of a subject with an agent, which kit comprises means for quantifying at least one biological marker of the invention that is indicative of the probability of occurrence of metastasis in a breast cancer patient.

Methods for Selecting Biological Markers Indicative of Metastasis

This invention also pertains to methods for selecting one or more biological markers that are indicative of the probability of occurrence of metastasis in one or more tissue or organ in a breast cancer-bearing patient.

The said tissue-specific marker selection method according to the invention preferably comprises the steps of:

-   -   a) providing means for detecting and/or quantifying one or more         biological markers in a tissue sample;     -   b) providing a plurality of collections of metastasis tissue         samples originating from breast cancer patients wherein each of         the said collection consists of a plurality of tissue samples         originating from metastasis originating from a unique tissue         type of metastatic breast cancer patients;     -   c) detecting and/or quantifying each of the one or more         biological markers, separately in every tissue sample contained         in each collection of tissue samples;     -   d) selecting, in the group of biological markers that are         detected and/or quantified at step c), those markers that are         expressed exclusively in only one collection of tissue samples         that is comprised in the plurality of collections of tissue         samples provided at step b), whereby a set of markers is         selected for each collection of tissue samples, the said set of         markers comprising markers, the expression of which is         indicative of the probability of occurrence of metastasis in a         specific tissue of a breast cancer patient.

For the purpose of performing the marker selection method above exclusively, the term “biological marker” is used in its conventionally acknowledged meaning by the one skilled in the art, i.e. herein a product of expression of any human gene, including nucleic acids and proteins.

Illustrative embodiments of the selection method above are fully described in the examples herein.

For performing step a) of the selection method above, the marker detection and/or quantification means encompass means for detecting or quantifying marker proteins, such as antibodies, or marker gene-specific nucleic acids, such as oligonucleotide primers or probes. Illustratively, DNA or antibodies microarrays may be used at step a) of the selection method above.

Means for specifically detecting and/or quantifying any one of the known biological marker, e.g. any known protein or any gene-specific nucleic acid, may be provided at step a) of the selection method.

Each collection of tissue samples that is provided at step b) of the selection method above comprises a number of metastasis tissue samples originating from a unique metastatic tissue (e.g. bone, lung, liver, brain and skin) that are collected from the same number of breast cancer-bearing individuals. Preferably, each collection of metastasis tissue samples comprises samples originating from at least 10 distinct breast cancer individuals, and most preferably at least 20, 25 or 30 distinct breast cancer individuals. The statistical relevance of the tissue-specific markers that are finally selected at the end of the selection method generally increases with the number of distinct breast cancer individuals tested, and thus with the number of metastasis tissue samples comprised in each collection that is provided at step b).

At step c), detection and/or quantification of the biological markers on the tissue samples provided at step b), using the detection and/or quantification means provided at step a), may be performed according to any one of the detection and/or quantification methods that are described elsewhere in the present specification.

At step d), each marker detected at step c) in a first specific collection of tissue samples (e.g. bone metastasis tissue) is compared to the detection and/or quantification results found for the same marker in all of the other collections of tissue samples (e.g. lung, liver and brain). Then, only those markers that are differentially expressed (i.e. (i) expressed, (ii) not expressed, (iii) over-expressed and (iv) under-expressed) in the said first collection of tissue samples, as compared to the other collections of tissue samples are positively selected as markers indicative of a probability of occurrence of breast cancer metastasis in the said specific tissue (e.g. bone metastasis tissue). At step d), the selection of statistically relevant metastasis tissue-specific markers, by comparing marker expression in one breast cancer metastatic tissue with the expression of the said marker in the group of all other distinct breast metastatic breast cancer tissue(s), is termed a “One Versus All” (“OVA”) pairwise comparison, as it is fully described in the examples herein.

The statistical relevance of each marker tested, at step d), may be performed by calculating the p value for the said marker, for example using a univariate t-test, as disclosed in the examples herein. Generally, a marker is selected at step d) of the selection method above, when its p value is lower than 10⁻³.

The statistical relevance of the marker selection, at step d) of the method, may be further increased by performing a multivariate permutation test, to provide 90% confidence that a false marker selection rate is less than 10%, as disclosed in the examples herein.

In view of further improving the relevancy of the marker selection, at step d), further selection filters may be included, such as removing every marker consisting of a tissue-specific gene, i.e. every marker that is selectively differentially expressed in a first specific normal non-cancerous tissue (e.g. bone), as compared to the other normal non-cancerous tissues (e.g. lung, liver, brain, etc.).

For further increasing the statistical relevance of the markers initially selected, at step d) of the selection method above, those markers that were initially selected as described above may be submitted to a further cycle of selection, for example by assaying the initially selected markers on further collections of breast cancer metastasis tissue samples. This further cycle of selection may consist of, for example, performing a further expression analysis of the initially selected markers, for example by technique of quantitative RT-PCR expression analysis, as shown in the examples herein. DNA microarrays may also be used.

According to such a quantitative RT-PCR expression analysis, the quantification measure of expression of each initially selected marker is normalised against a control value, e.g. the quantification measure of expression of a control gene such as TBP. The results may be expressed as N-fold difference of each marker relative to the value in normal breast tissues. Statistical relevance of each initially selected marker is then confirmed, for example at confidence levels of more than 95% (P of less than 0.05) using the Mann-Whitney U Test (SEM), as described in the examples herein.

The present invention is further illustrated by, without in any way being limited to, the examples below.

EXAMPLES Examples 1 and 2 A. Materials and Methods of the Examples 1 and 2 A.1. Tissue Samples

A total of 33 metastases from human breast cancer were used for microarray and quantitative RT-PCR analyses. These samples were snap-frozen in liquid nitrogen and stored at ±196° C. Seven bone metastases (osteolytic type) and 6 normal bone samples were obtained from University of L'Aquila (L'Aquila, Italy), 4 brain metastases and 4 normal brain samples from IDIBELL (Barcelona, Spain). All other metastatic samples (8 lung, 8 liver and 6 skin metastases) and the 35 breast primary tumors samples were obtained from Centre René Huguenin (Saint-Cloud, France). All these primary tumor samples were resected from female patients who did not receive chemotherapy. Normal breast, lung, brain and liver RNA samples were purchased from Clontech, Biochain and Invitrogen. Normal tissue RNA pools were prepared with at least 5 samples each. Publicly available microarray data of a cohort of breast primary tumors with clinical follow up (with known site of relapse: bone, lung and other) were downloaded as on the NCBI website (GSE2603 record).

Additional breast cancer metastatic paraffin-embedded samples were obtained from the Department of Pathology (Pr. J. Boniver) at the University of Liège, Belgium (12 bone, 6 liver, 4 lung), from IDIBELL, Spain (6 brain), from the Anatomopathology Department of the Centre René Huguenin, France (2 lung and 1 liver) and used for the immunohistochemical analysis.

A.2. RNA Extraction

Total RNA was isolated from human samples using TRIzoL® Reagent from Gibco, as described by the manufacturer. RNA was quantified by absorbance at 260 nm (Nanodrop). Quality of the RNA samples was assessed by agarose gel electrophoresis and the integrity of 18S and 28S ribosomal RNA bands. Total RNA used for microarray analysis was further purified using RNeasy® spin columns (Qiagen) according to the manufacturers' protocols.

A.3. Probe Preparation and Microarray Hybridization

Sample labeling, hybridization, and staining were carried out according to the Eukaryotic Target Preparation protocol in the Affymetrix® Technical Manual (701021 Rev. 5) for GeneChip® Expression analysis (Affymetrix). In summary, 500 ng-10 μg of purified total RNA was used to generate double-stranded cDNA using a GeneChip Expression 3′-Amplification One-Cycle cDNA synthesis Kit and a T7-oligo(dT) primer (Affymetrix). The resulting cDNA was purified using the GeneChip Sample Cleanup Module according to the manufacturers' protocol (Affymetrix). The purified cDNA was amplified using GeneChip Expression 3′-Amplification Reagents For IVT Labelling (Affymetrix) to produce 20-70 μg of biotin labeled cRNA (complement RNA). 13 μg of labeled cRNA (per array) was fragmented at 94° C. for 35 min. The fragmented cRNA was hybridized to the Human Genome U133 Plus 2.0 Array for 16 h at 45° C.

The hybridized arrays were washed and stained using Streptavidin-Phycoerythrin (Molecular Probes) and amplified with biotinylated anti-streptavidin (Vector Laboratories) using a GeneChip Fluidics Station 450 (Affymetrix). The arrays were scanned in an Affymetrix GeneChip scanner 3000 at 570 nm. The 5′/3′ GAPDH ratios averaged 3.5 and the average background, noise average, % Present calls and average signal of the Present calls were comparable for all the arrays utilized in this experiment. U133 Plus 2.0 expression arrays contain 56000 probe sets corresponding to 47000 transcripts.

A.4. Microarray Statistical Analysis

Expression profiles were analyzed with BRB Array tools, version 3.3beta3 (Biometric Research Branch, Division of Cancer Treatment and Diagnosis Molecular Statistics and Bioinformatics Section, National Cancer Institute, Bethesda, Md., USA). Microarray data were collated as CEL files, calculation of Affymetrix probe set summaries and quantile normalization were done using RMA function of Bioconductor. We developed 4 raw site-specific metastatic signatures: bone, brain, liver and lung metastases. We used 6 bone, 4 brain, 6 liver, 5 lung and 2 skin metastases. We divided the multiclass problem into a series of 4 “One Versus All” (OVA) pairwise comparisons. For example, the raw bone metastasis signature was defined as follow: we selected probes differentially expressed between “Bone metastases” vs “All other metastases”, i.e. “Bone metastases” vs “Lung+Liver+Brain+Skin metastases”.

We identified genes that were differentially expressed among the two classes using a univariate t-test. Genes were considered statistically significant if their p value was less than 0.0001. A stringent significance threshold was used to limit the number of false positive findings.

We defined several selection filters. First, we identified potential host-tissue genes that could originate from contamination. Genes are considered as putative host-tissue genes if they are 1.5-fold more expressed in the corresponding normal tissue pool (e.g. bone) than in each of the other 3 normal tissue pools (i.e. liver, brain and lung). Second, upregulated genes with a geometric mean of intensities below 25 in the corresponding class (e.g., bone metastases) are removed. Downregulated genes with a geometric mean of intensities below 25 in the “other metastases” class (e.g. liver, brain, lung and skin metastases) are removed. Finally, probes were aligned against human genome (using Blast software from NCBI website). They were not conserved when they do not recognize transcripts. Metastatic signatures contain remaining most differentially expressed genes (sorted by absolute t-value) and were tested by quantitative RT-PCR.

A.5. Quantitative RT-PCR Expression Analysis

cDNA of human samples used for real-time RT-PCR analysis were synthesized as previously described (Bieche et al., 2001). All of the PCR reactions were performed using a ABI Prism 7700 Sequence Detection System (Perkin-Elmer Applied Biosystems) and the SYBR Green PCR Core Reagents kit (Perkin-Elmer Applied Biosystems). 10 μl of diluted sample cDNA (produced from 2 □g of total RNA) was added to 15 μl of the PCR master-mix. The thermal cycling conditions were composed of an initial denaturation step at 95° C. for 10 min, and 50 cycles at 95° C. for 15 s and 65° C. for 1 min.

Human RNAs from primary tumors and relapses were analyzed for expression of 56 genes selected among the organ-specific metastasis associated genes by using quantitative real-time reverse transcription-PCR (RT-PCR) assay, as previously described (Bieche et al., 2001). Expression of these genes were measured in 29 metastatic samples from human breast cancer including 19 already tested by microarray and10 new samples (1 bone, 3 lung, 2 liver, and 4 skin relapses). TATA-box-binding protein (TBP) transcripts were used as an endogenous RNA control, and each sample was normalized on the basis of its TBP content. Results, expressed as N-fold differences for each X gene expression relative to the TBP gene (termed “N_(X)”), were obtained with the formula N_(X)=2^(ΔCtsample), where the ΔCt (Δ Cycle Threshold) value of the sample was determined by subtracting the average Ct value of the X gene from the average Ct value of the TBP gene. The N_(X) values of the samples were subsequently normalized such that the median of the N_(X) values of the four normal breast samples would have a value of 1. The nucleotide sequences of the primers used for real-time RT-PCR amplification are described in Table 3. Total RNA extraction, cDNA synthesis and the PCR reaction conditions have been previously described in detail (Bieche et al., 2001, Cancer Res, Vol 61(4): 1652-1658).

Differences between two populations were judged significant at confidence levels>95%, (P<0.05), using Mann Whitney UTest (SEM)

ImmunoHistoChemistry

Metastatic biopsies from breast cancer patients were fixed in 4% formaldehyde in 0.1 M phosphate buffer, pH 7.2, and embedded in paraffin. Bone specimens were decalcified either with a solution of ethylenediaminetetraacetic acid (EDTA) and hydrochloric acid (Decalcifier II, Labonord) or with a solution of formalin (20%) and nitric acid (5%). Sections were cut using a Reichert-Jung 1150/Autocut microtome. Slide-mounted tissue sections (4 μm thick) were deparaffinized in xylene and hydrated serially in 100%, 95%, and 80% ethanol. Endogenous peroxidases were quenched in 3% H₂O₂ in PBS for 1 hour, then slides were incubated with the indicated primary antibodies overnight at 4° C. Sections were washed three times in PBS, and antibody binding was revealed using the Ultra-Vision Detection System anti-Polyvalent HRP/DAB kit according to the manufacturer's instructions (Lab Vision). Finally, the slides were counterstained with Mayer's hematoxylin and washed in distilled water.

The anti-OMD and the anti-IBSP antibodies were kindly provided respectively by Dick Heinegard (Department of Experimental Medical Science, Lund University), Sweden and L.W. Fisher (National Institute of Dental Craniofacial Research, NIH, Bethesda, Md., USA). The anti-KIND1 and anti-TOP1 antibodies were purchased from Abcam, the anti-MMP-9 from Chemicon, and anti-DSC2 antibody from Progen respectively.

Example 1 Identification of Differentially Expressed Genes

We compared the transcriptional profiles of human breast cancer metastases from the four main target organs of relapse: bone, lung, liver and brain. Therefore, using microarray gene expression data (Affymetrix U133 Plus 2.0 chips), we examined 23 metastatic samples obtained from surgery.

To identify genes that were specifically expressed in each of the 4 metastatic organs, we performed one-versus-all (OVA) class comparisons to distinguish two known subgroups. We used the following combinations: 6 bone metastases versus all 17 others (non-bone metastases), 5 lung metastases versus 18 others, 6 liver metastases versus 17 others and 4 brain metastases versus 19 others. Gene expressions between two defined groups were compared by use of a univariate t-test, in which the critical p-value was set at 10⁻⁴.

After applying filtering criteria as described in Materials and Methods, we identified 4 gene lists corresponding to the genes differentially expressed in bone metastases (325 probes representing 276 genes), lung metastases (28 probes representing 23 genes), liver metastases (114 probes representing 83 genes) and brain metastases (133 probes representing 123 genes) (Table 1). Among the 600 identified probes (representing 505 genes), 77% were upregulated and 23% were downregulated. The bone and brain metastasis associated genes were downregulated in approximately 30% of the cases whereas the lung and liver metastasis associated genes were downregulated in about 5%. The 20 highest-ranking genes for each organ specific metastasis are illustrated in Table 2.

In order to validate at the protein level the observations made at the RNA level, we proceeded to immunohistochemistry analyses of several organ-specific metastatic gene products: DSC2 and KIND1 associated to lung metastasis and TOP1 corresponding to the brain metastatic process. As expected, proteins were highly expressed most exclusively by metastatic cells. KIND1 and TOP1 are highly and homogeneously expressed by metastatic cells, whereas DSC2 is principally highly expressed by metastatic cells present on the edge of the tumor, suggesting the presence of a cross talk with lung cells.

1.1. Main Biological Processes Involving Organ-Specific Metastasis Associated Genes

All the differentially expressed genes associated to the four sites of relapse were mapped to the Gene Ontology database. Among the 505 genes tested, 326 were annotated for the “Gene Ontology Biological Process Description”. The descriptions were classified in major biological processes (i.e., apoptosis, cell adhesion, cell cycle, cell signaling, cytoskeleton organization, RNA processing, transcription regulation) to determine whether certain processes were highly represented. Thereby, we observed that the “cell adhesion” related genes were represented in 4 out of 15 (26.6%) annotations in the lung metastasis list. For the liver and brain metastasis associated genes the “transcription regulation” was the most represented description in 21/58 (32.2%) and 20/63 (31.7%) respectively. In the bone metastasis gene list, the genes related to “cell signaling” were the most frequently found (61/190, i.e. 32.1%). In addition, as previously described, the bone metastasis associated genes contains high proportion of genes involved in immune response (Smid et al., 2006,). Highly represented annotations in each of the organ-specific metastatic gene list might point to particular biological processes, which are potentially linked to the site of relapse.

Among the “known” proteins identified, several have already been involved in cancer progression and/or metastatic phenotypes, such as the genes PTEN, PERP, PDGFRA, TBX3 (Attardi et al., 2000; Petrocelli et al., 2001; Rowley et al., 2004; Oliveira et al., 2005; Jechlinger et al., 2006). Among the liver metastasis associated genes, WHSC1L1 and LETM2 are of particular interest since they have been described as coamplified in lung cancer. Their upregulation is probably due to a genetic event in cancer cells (Tonon et al, 2005). The brain metastasis associated gene HOXB13 overexpression was recently associated with the clinical outcome in breast cancer patients (Ma et al., 2006). Moreover, among the bone metastasis associated genes, MFNG encodes Manic Fringe protein which modulates the Notch signaling pathway. This pathway has been reported to be involved in bone metastasis of prostate cancer (Zayzafoon et al, 2003), while TNFAIP8L2 and CSF-1 could be implicated in the enhancement of osteoclast formation and activity typically observed in breast cancer bone metastases.

1.2. Interaction with the Microenvironment in the Case of Bone Metastasis: Osteomimicry

Among the genes that were found differentially expressed in bone metastases but that were removed by our filtering criteria to avoid host-tissue genes (due to contamination), we identified several genes known to be expressed by cells of the osteoblastic lineage such as bone sialoprotein (IBSP) and osteocalcin (BGLAP) noncollagenous bone matrix proteins. We observed that metastatic breast cancer cells localized in bone consistently showed a strong immunoreactivity to IBSP, MMP9 and OMD in the majority of the samples analyzed. This observation is consistent with previous reports indicating that breast and prostate cancer cells metastasizing to bone express bone-related proteins (Koeneman 1999, Waltregny, 2000, Huang 2005). This phenomenon, named <<osteomimicry >>, could explain the propensity of osteotropic cancer cells to metastasize to the skeleton (Koeneman 1999).

1.3. Organ-Specific Metastatic Signature

The genes differentially expressed in the 4 target organs (Table 2) were then analyzed to define an organ-specific metastatic signature. Among these genes, 56 were tested by quantitative RT-PCR on a series of 29 breast cancer metastases consisting of 19 distant relapses already used for microarray analysis (4 bone metastases, 5 lung metastases, 6 liver metastases, 4 brain metastases) and 10 additional samples (1 bone metastasis, 3 lung metastases, 2 liver metastases and 4 skin metastases).

Thirty one genes (55%) passed the comparison criteria (OVA comparison, Mann Whitney U test, p value<0.05) (supplementary table 3). The combination of these validated genes was evaluated as the organ-specific metastatic signature by hierarchical clustering. As shown by the dendrogram, the signature clearly separated the different metastatic classes. Remarkably, the bone metastases cluster seemed separated from the soft tissue metastases clusters. Our restricted “31-gene signature” showed similar patterns than the 80 highest-ranking genes (data not shown).

1.4. Predictive value of the organ-specific metastatic signature

The actual assumption is that primary tumors may already contain a gene expression profile that is strongly predictive of metastasis and in addition, tumor cells could also display a tissue-specific expression profile predicting the site of metastasis. To test this hypothesis, a series of publicly available microarray data relative to a cohort of 82 breast cancer patients with follow up (especially site of relapse) was analyzed (Minn et al, 2005a). In this series, 27 tumors relapsed, mainly in bone or lungs. Therefore, our identified lung- and bone-metastasis associated genes (only 6 and 10 genes respectively present on U133A chips) were used to cluster the 27 relapsing tumors (data not shown). We observed, in both cases, that many genes were expressed in the same way in relapsing tumors as the corresponding relapses. For example, genes upregulated or downregulated in bone metastases presented respectively higher or lower expression in breast tumor relapsing to bone than in those relapsing elsewhere.

Furthermore, primary tumors that highly express these bone metastasis genes seemed more susceptible to relapse to bone (p=0.082, χ² test). In the same way, primary tumors that highly express these lung metastasis genes were significantly more susceptible to relapse to lung (p=0.002, χ² test) (FIG. 1).

Finally, we evaluated the predictive value of our organ-specific signature on the large cohort of 82 primary tumors. The organ-specific metastatic signature (represented by only 25 probes present on U133A chips) allowed a classification of those tumors within 3 main clusters corresponding to tumors giving rise mainly to lung metastases, bone metastases and no metastasis (FIG. 2).

Kaplan Meier analyses were performed to assess the prognostic value of the signature with respect to organ-specific-metastasis-free survival. Patients with tumors expressing lung metastasis genes (cluster #1) had worse lung-metastasis-free survival (p=0.00066) but not bone-metastasis-free survival (data not shown). Patients with tumors expressing bone metastasis genes (cluster #2) showed a tendency to have a worst bone-metastasis free survival (p=0.12), and the patients included in the cluster #3 (tumors expressing neither bone nor lung metastasis genes) had a better metastasis free survival.

To confirm these results, we performed an analysis of the expression of the organ-specific metastatic signature by quantitative RT-PCR in an independent cohort of 35 patients. These patients were treated at Centre René Huguenin, did not receive chemotherapy and did all present relapses to bone or lung. Tumors that highly express lung metastasis genes (7 genes) significantly relapsed more to lung (p=0.04, χ² test). Patients who presented these latter tumors had a significantly worst lung metastasis free survival (p=0.00043, 10 years after diagnosis of the primary tumor. However, tumors that express bone metastasis genes did not relapsed more to bone (data not shown).

Examples 3 to 6 A. Materials and Methods of Examples 3 to 6 A.1. Patients and Samples

The study was performed according to the local ethical regulations. We first studied the transcriptome of 23 metastases (5 lung, 6 liver, 4 brain, 2 skin and 6 osteolytic bone metastases) from breast cancer patients that undergone surgery (n=22). Then, additional 10 samples were used for RT-PCR validation (3 lung, 2 liver, 4 skin and 1 bone metastases) (n=10). All metastatic samples were obtained from University of L'Aquila (L'Aquila, Italy), IDIBELL (Barcelona, Spain) and Centre René Huguenin (CRH, Saint-Cloud, France). Normal-tissue RNA pools were prepared from 6 bone (L'Aquila), 4 brain (IDIBELL), and at least 5 breast, lung, and liver normal samples purchased from Clontech (Palo Alto, USA), Biochain (Hayward, USA) and Invitrogen (Frederick, USA).

A series of 72 primary breast tumors (“CRH cohort”) was specifically selected from patients with node-negative breast cancer treated at the Centre René Huguenin, and who did not receive systemic neoadjuvant or adjuvant therapy (median follow-up of 132 months, range 22.6 to 294 months). During 10 years of follow-up, 38 patients developed distant metastases. Eleven of these patients developed lung metastases as the first site of distant relapse.

We also analyzed 3 independent breast tumor series; the “MSK” (n=82), “EMC” (n=344) and “NKI” (n=295) cohorts described in detail elsewhere (4, 6, 12, 14) for which microarray data can be freely downloaded from the NCBI website. Briefly, “EMC” and “NKI” cohorts consist of early stage breast cancers 100% and 50% lymph node-negative, respectively whereas “MSK” series is consisting of locally advanced tumors, 66% node-positives).

Finally, paraffin-embedded sections of lung metastases and paired breast tumors were obtained from Liege University (Belgium) and from Centre Rene Huguenin (France) to perform immunohistological analyses.

A.2. Gene Expression Analysis

For microarray analysis, sample labeling, hybridization, and staining were carried out as previously described (Jackson et al., 2005). Human Genome U133 Plus 2.0 arrays were scanned in an Affymetrix GeneChip scanner 3000 at 570 nm. The 5′/3′ GAPDH ratios averaged 3.5. The average background, noise average, % Present calls and average signal of Present calls were similar with all the arrays used in this experiment.

For quantitative RT-PCR analysis, we used cDNA synthesis and PCR conditions described in detail elsewhere (34). All PCR reactions were performed with an ABI Prism 7700 Sequence Detection System (Perkin-Elmer Applied Biosystems) and the SYBR Green PCR Core Reagents kit (Perkin-Elmer Applied Biosystems). TATA-box-binding protein (TBP) transcripts were used as an endogenous RNA control, and each sample was normalized on the basis of its TBP content (Bieche et al., 2001).

A.3. Immunohistochemistry

Biopsy specimens of primary tumors and matching lung metastases from breast cancer patients were fixed and embedded in paraffin. Sections 4 μm thick were deparaffinized in xylene and hydrated in serial ethanol concentrations. Endogenous peroxidases were quenched in PBS containing 3% H₂O₂ for 1 hour, then the slides were incubated with the indicated primary antibodies overnight at 4° C. Sections were washed, and antibody binding was revealed with the Ultra-Vision Detection System Anti-Polyvalent HRP/DAB kit (Lab Vision). Finally, the slides were counterstained with Mayer's hematoxylin and washed in distilled water. The anti-FERMT1 and anti-DSC2 antibodies were purchased from Abcam (Cambridge, USA) and Progen (Queensland, Australia), respectively.

A.4. Statistical analysis

Microarray expression profiles were analyzed with BRB Array tools, version 3.3beta3 developed by Richard Simon and Amy Peng Lam (http://linus.nci.nih.gov/BRB-ArrayTools.html). Expression data were collated as CEL files, and calculation of Affymetrix probe set summaries and quantile normalization were done using the RMA function of Bioconductor. Univariate t tests were used to identify genes differentially expressed between 5 lung metastases and 18 non lung metastases (6 bone, 4 brain, 6 liver, and 2 skin). Differences were considered statistically significant if the p value was less than 0.0001. This stringent threshold was used to limit the number of false-positives.

Several selection filters were used to refine the lung metastasis-related gene set. First, we filtered potential host-tissue genes characterized by a 1.5-fold higher expression level in normal lung tissue than in each of the other three normal tissue pools (bone, liver and brain). These genes were considered as potentially expressed by contaminating host tissue. Second, genes with geometric mean intensities below 25 in both lung and non lung metastases were removed. Finally, probes aligned against human genome (using Blast software from the NCBI website) not recognizing any transcripts were excluded.

Genes of interest were mapped between different platforms by using Unigene identifiers. The individual breast cancer series were then analyzed with the same probes when possible. To determine whether gene expression profiles were able to define low- and high-lung metastasis risk populations in the CRH cohort, the six-gene signature was used to create a risk index defined as a linear combination of the gene expression values. The distribution of risk index values was examined to determine the optimal cut point at the 75^(th) percentile to distinguish high and low risk in the CRH series. The risk index function and the high/low risk cutoff point were then applied to the MSK, EMC, NKI and combined cohorts.

Survival times were estimated by the Kaplan-Meier method, and the significance of differences was determined with the log-rank test. Multivariate analyses were performed using the Cox proportional hazards regression model.

Example 3 Identification of Lung Metastasis-Associated Genes

We first performed a microarray analysis to compare the gene transcript profiles of 5 lung metastases and 18 metastases from other target organs (bone, liver, brain and skin), all obtained from breast cancer patients undergoing surgery. A class comparison was conducted based on a univariate t test, with a stringent p value of 10⁻⁴, to identify genes differentially expressed by the two tissue categories.

After applying filtering criteria (see Patients and Methods), we identified 21 differentially expressed genes (19 known and 2 unknown genes) (Table 5), mostly overexpressed in lung metastases. Only one gene, the tumor suppressor gene PTEN, was down-regulated.

To technically validate the differentially expressed genes, we examined the expression of the highest-ranking genes by quantitative RT-PCR using 19 samples analyzed by microarray (4 had no more RNA available) and 10 additional breast cancer metastases including 3 lung relapses. This validation step led to the selection of 7 genes showing a significant variation of expression, namely DSC2, HORMAD1, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1 (Table 5).

Furthermore, to verify that these observed differentially expressed profiles were due to the metastatic samples but not to differential expression of adjacent host tissues, we evaluated the protein expression for 2 representative genes: DSC2 and FERMT1 (corresponding to the upper and lower p values, Table 5). Strong immunoreactivity was detected for both proteins, almost exclusively in the tumor cells, and not in the surrounding pulmonary tissue.

The characterized genes were mapped into the Gene Ontology and Kyoto Encyclopedia of Genes and Genomes (KEGG) databases to investigate their functions and biological processes (Table 5). Interestingly, the lung metastasis-related genes showed an overrepresentation of membrane-bound molecules mainly involved in cell adhesion and/or signal transduction (DSC2, UGT8, ITGB8, FERMT1). Very little is known on the other identified genes (HORMAD1, TFCP2L1 and ANP32E). None of these proteins have been previously shown to be specifically involved in metastasis.

Example 4 Development of a Predictor of Selective Breast Cancer Failure to the Lungs

To determine whether the 7 lung metastasis-associated genes could already be expressed in primary breast tumor cells and whether they could be predictive of a higher risk of lung metastasis, we analyzed by qRT-PCR their expression patterns in a series of 5 normal breast tissue samples, 6 breast cancer cell lines (MCF7, T47D, SKBR3, MDA-MB-231, MDA-MB-361 and MDA-MB-435) and 44 primary breast tumors. All lung-metastasis-associated genes were expressed in tissues of mammary origin except HORMAD1 that showed very weak to no expression in all normal breast, all cell lines and a majority of primary tumors (Ct<35). Therefore, HORMAD1 was not considered in our attempt to establish a lung metastasis signature.

The 6 remaining genes (DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1) were used to develop a gene signature predictive of a higher risk of lung metastasis. We studied a cohort of 72 lymph-node-negative patients specifically selected on the basis of the treatments and metastatic outcomes: the CRH cohort. All 72 patients had not received neoadjuvant or adjuvant therapy. This meant that the potential prognostic impact of the “lung-metastasis classifier” would not be influenced by factors related to systemic treatment. Thirty-eight patients had developed distant metastases within 10 years (including 11 with lung metastases) and 34 patients remained free of disease after their initial diagnosis for a period of at least 10 years (Table 6).

The primary tumors were then assigned to a high-risk group or a low-risk group, with respect to lung metastasis, according to the risk index calculated on the basis of the six-gene signature. The lung metastasis risk index was defined as the linear combination of the expression values of the 6 genes and the appropriate cutoff point was set at the 75^(th) percentile. Tumors expressing high levels of the risk index metastasized significantly more frequently to the lungs than did the other tumors (p=0.04, χ² test, FIG. 3A). In addition, patients with such tumors had significantly shorter lung-metastasis-free survival (p=0.008 FIG. 3B). The six-gene signature did not correlate with the risk of bone metastasis (FIG. 3C) or liver metastasis (FIG. 3D).

Example 5 Validation of the Predictive Ability of the Six-Gene Signature

To validate the predictive value of the six-gene lung metastasis signature, we analyzed expression profiles of 3 independent cohorts of breast cancer patients which microarray data are publicly available (Wang et al., 2005; Van de Vijver, 2002; Minn et al., 2005, Minn et al., 2007). These 3 datasets correspond to 2 large cohorts of early stage breast cancer patients (“NKI” and “EMC” series of 295 and 344 patients, respectively) and a more locally advanced cohort of breast cancers (the “MSK” cohort of 82 patients) (Wang et al., 2005; Van de Vijver, 2002; Minn et al., 2005, Minn et al., 2007).

Hierarchical clustering analysis was performed on all individual series. Within the 3 different cohorts, the six-gene signature discriminates a subgroup of breast tumors with a higher propensity to metastasize to the lungs (p=0.04, p=0.016 and p=0.014, χ² test, for MSK, EMC and NKI respectively). As representative results, the clustering of the MSK and NKI breast tumors have been performed.

The results of hierarchical clustering are only indicative. Thus, using the same procedure as for the CRH cohort, we evaluated the six-gene signature in the 3 independent cohorts. Patients assigned to the high-risk group had significantly shorter lung-metastasis-free survival in all cases (p=0.004, 0.001 and 0.039 for MSK, EMC and NKI series respectively, FIG. 4), whereas there was no difference in bone-metastasis-free survival. It is noteworthy that there is a fewer discrimination in NKI cohort, probably due to the consideration of only 5 genes of the signature since one gene (ANP32E) was not present in the corresponding chips. Finally, the Kaplan-Meier analysis was also performed on the combined cohort and resulted in a highly significant correlation of the six-gene signature with the outcome of breast cancer patient with regard to lung metastasis (n=721, p<10⁻⁵).

Example 6 Correlation to standard Clinico-Pathological Variables and Other Prognostic Signatures

We evaluated whether the six-gene signature provided additional prognostic information that may not be obtained by other models and/or standard markers. First, we analyzed the NKI series (for which the complete clinical data were documented) for the main prognostic molecular signatures reported for breast cancers. Consistent with previous reports, the primary breast tumors expressing the six-gene signature also expressed other poor-prognosis molecular markers (Kang et al., 2003; Minn et al., 2007). The tumors of patients at risk for lung metastasis as defined by the six-gene signature mostly were of poor prognosis on the basis of standard pathological parameters (62% ER-negative and 70% grade 3) and previously reported poor-prognosis signatures as the 70-gene signature (van't Veer et al., 2002; van de Vijver et al., 2002), the wound-healing signature (Chang et al., 2005; Chang et al., 2005) and the basal-like molecular subtype (23, 24) (80%, 89%, and 58% respectively).

In addition, when analyzing the clinicopathological variables available for each of the cohorts of breast cancer patients, we found no difference between the high- and low-risk groups with respect to age, lymph node status or primary tumor size, whereas most high-risk patients and their tumors appeared to be hormone receptor-negative and grade 3.

To ensure that the six-gene classifier improved risk stratification independently of these standard clinical parameters, we performed a multivariate Cox proportional-hazards analysis on the combined cohort (n=721) (only estrogen-receptor and lymph node status parameters were available for all patients, Table 7). The Cox model showed that the six-gene signature and estrogen receptor status were independent predictors of lung metastasis (p=0.01 and 0.04 respectively). The six-gene signature is a significant predictor of lung metastasis in breast cancer. It added new and important prognostic information beyond that provided by ER and lymph node status.

Finally, we compared the predictive value of our lung metastasis signature to the one derived from the MDA-MB-231 mouse model (LMS) (Minn et al., 2007). These two signatures are defined by expression patterns of distinct sets of genes with no overlap. When evaluated on the same series of 721 samples, we observe that despite their different derivations, the signatures gave overlapping and consistent predictions outcome. Each signature assigned the same patients to the high or low risk groups of breast cancer lung metastasis. Indeed, the two models have high level of concordance in their predictions of lung metastasis. Almost all tumors identified as LMS were also classified as having the six-gene signature. LMS and our six-gene signature showed 85% agreement in outcome classification of breast cancer patients with respect to lung metastasis (Kappa coefficient=0.57). These results suggest that even though there are no gene overlap and different biological models were used, the outcome predictions still are similar, probably because they track common set of biological characteristics conferring the organ-specific metastatic phenotypes.

Thus, to determine whether the use of the two models together would result in a better model than the use of any one alone, we derived a single model based on the common findings of the 2 models separately. The performance of this model according to the Kaplan-Meier analysis was noticeably better than each of the 2 models (FIG. 5B) demonstrating that gene signatures derived from 2 distinct approaches can be complementary, as recently reported for the 70-gene and WR signatures corresponding to the “top-down” and “bottom-up” strategies respectively (Chang et al., 2005).

Further, as shown in FIG. 6, primary that highly express eleven-gene bone metastasis signature are more susceptible to relapse to bone.

Also, Table 8 shows the highets ranking genes obtained from a class comparison of bone and non-bone metastases of breast cancer.

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TABLE 1 Geometric mean of Parametric p- intensities in ratio Probe Set Gene Gene Title value Bone Non_Bone BONE Symbol METASTASIS ASSOCIATED MARKERS metastases metastases 221724_s_at CLEC4A C-type lectin domain family 4, p < 0.000001 55.9 22.8 2.45 member A 204153_s_at MFNG manic fringe homolog (Drosophila) p < 0.000001 92.7 34.5 2.69 208922_s_at NXF1 nuclear RNA export factor 1 p < 0.000001 281.2 174.6 1.61 227002_at FAM78A family with sequence similarity 78, p < 0.000001 91.2 37.6 2.43 member A 226245_at KCTD1 potassium channel tetramerisation p < 0.000001 60.7 199.2 0.30 domain containing 1 227372_s_at BAIAP2L1 BAI1-associated protein 2-like 1 p < 0.000001 23.6 245.8 0.10 206060_s_at PTPN22 protein tyrosine phosphatase, non- p < 0.000001 64.3 15.6 4.12 receptor type 22 (lymphoid) 232523_at MEGF10 multiple EGF-like-domains 10 p < 0.000001 119.6 11.1 10.77 222392_x_at PERP PERP, TP53 apoptosis effector p < 0.000001 215.2 2340 0.09 211178_s_at PSTPIP1 proline-serine-threonine phosphatase p < 0.000001 60.2 20 3.01 interacting protein 1 204236_at FLI1 Friend □aematolo virus integration 1 p < 0.000001 79.7 16.6 4.80 213290_at COL6A2 collagen, type VI, alpha 2 p < 0.000001 99.2 37.7 2.63 203547_at CD4 CD4 molecule p < 0.000001 240.3 91.6 2.62 205382_s_at CFD complement factor D (adipsin) p < 0.000001 601.4 81.6 7.37 235593_at ZFHX1B zinc finger homeobox 1b p < 0.000001 35.6 12.2 2.92 206120_at CD33 CD33 molecule p < 0.000001 93.6 40.2 2.33 214181_x_at LST1 leukocyte specific transcript 1 p < 0.000001 242 62.5 3.87 219091_s_at MMRN2 multimerin 2 p < 0.000001 128.3 43.4 2.96 1552667_a_at SH2D3C SH2 domain containing 3C p < 0.000001 48.3 20.9 2.31 205326_at RAMP3 receptor (calcitonin) activity modifying p < 0.000001 163 83.8 1.95 protein 3 221565_s_at FAM26B family with sequence similarity 26, p < 0.000001 164.5 82 2.01 member B 201234_at ILK integrin-linked kinase p < 0.000001 462.9 208.5 2.22 219892_at TM6SF1 transmembrane 6 superfamily p < 0.000001 107.4 19.8 5.42 member 1 226345_at CDNA FLJ12853 fis, clone p < 0.000001 61.7 200.1 0.31 NT2RP2003456 225373_at C10orf54 chromosome 10 open reading frame p < 0.000001 238.6 77 3.10 54 205200_at CLEC3B C-type lectin domain family 3, p < 0.000001 201.7 37.9 5.32 member B 204116_at IL2RG interleukin 2 receptor, gamma 1.00E−06 226 69.2 3.27 (severe combined immunodeficiency) 209721_s_at HOM-TES- hypothetical protein LOC25900, 1.00E−06 128.7 62.8 2.05 103 isoform 3 237861_at ZNF23 Zinc finger protein 23 (KOX 16) 1.00E−06 48.6 29.6 1.64 225649_s_at STK35 serine/threonine kinase 35 1.00E−06 201.3 542.1 0.37 217744_s_at PERP PERP, TP53 apoptosis effector 2.00E−06 48.6 611.5 0.08 223583_at TNFAIP8L2 tumor necrosis factor, alpha-induced 2.00E−06 48.5 23 2.11 protein 8-like 2 205779_at RAMP2 receptor (calcitonin) activity modifying 2.00E−06 122.3 51.2 2.39 protein 2 201809_s_at ENG endoglin (Osler-Rendu-Weber 2.00E−06 330.6 126.4 2.62 syndrome 1) 223717_s_at ACRBP acrosin binding protein 2.00E−06 53.1 30.3 1.75 228258_at TBC1D10C TBC1 domain family, member 10C 2.00E−06 112.8 42.4 2.66 221637_s_at C11orf48 chromosome 11 open reading frame 2.00E−06 138.7 297.8 0.47 48 201323_at EBNA1BP2 EBNA1 binding protein 2 3.00E−06 66.4 190.6 0.35 229099_at CDNA clone MGC: 87549 3.00E−06 49.2 124.5 0.40 IMAGE: 30347387 205133_s_at HSPE1 heat shock 10 kDa protein 1 3.00E−06 338.6 1156.2 0.29 (chaperonin 10) 202177_at GAS6 growth arrest-specific 6 3.00E−06 248.7 60.7 4.10 208018_s_at HCK hemopoietic cell kinase 3.00E−06 253.1 46.3 5.47 204430_s_at SLC2A5 solute carrier family 2 (facilitated 3.00E−06 124 22.5 5.51 glucose/fructose transporter), member 5 225562_at RASA3 RAS p21 protein activator 3 3.00E−06 126.2 63.3 1.99 1554628_at ZNF57 zinc finger protein 57 3.00E−06 18.3 57.6 0.32 202665_s_at WASPIP Wiskott-Aldrich syndrome protein 3.00E−06 104.1 43.8 2.38 interacting protein 204678_s_at KCNK1 potassium channel, subfamily K, 3.00E−06 20.2 101.9 0.20 member 1 214847_s_at GPSM3 G-protein signalling modulator 3 3.00E−06 115.2 57 2.02 (AGS3-like, C. elegans) 230800_at ADCY4 adenylate cyclase 4 4.00E−06 136.9 82.2 1.67 211133_x_at LILRB2/ leukocyte immunoglobulin-like 4.00E−06 189.6 117.5 1.61 LILRB3 receptor, subfamily B (with TM and ITIM domains), member 2/leukocyte immunoglobulin-like receptor, subfamily B (with TM and ITIM domains), member 3 215051_x_at AIF1 allograft inflammatory factor 1 4.00E−06 644.5 213.6 3.02 202663_at WASPIP Wiskott-Aldrich syndrome protein 4.00E−06 53.9 19.4 2.78 interacting protein 207738_s_at NCKAP1 NCK-associated protein 1 4.00E−06 426.5 874.1 0.49 228094_at AMICA1 adhesion molecule, interacts with 4.00E−06 110.4 43.7 2.53 CXADR antigen 1 209482_at POP7 processing of precursor 7, 4.00E−06 162.8 370.4 0.44 ribonuclease P subunit (S. cerevisiae) 204220_at GMFG glia maturation factor, gamma 4.00E−06 457.8 108.8 4.21 226074_at PPM1M protein phosphatase 1M (PP2C 4.00E−06 102.5 56.6 1.81 domain containing) 226056_at CDGAP Cdc42 GTPase-activating protein 4.00E−06 34.8 18.7 1.86 213095_x_at AIF1 allograft inflammatory factor 1 4.00E−06 630.7 181.1 3.48 1552318_at GIMAP1 GTPase, IMAP family member 1 5.00E−06 25.6 12.6 2.03 227780_s_at 5.00E−06 152 66.7 2.28 232543_x_at ARHGAP9 Rho GTPase activating protein 9 5.00E−06 209.6 57.9 3.62 220023_at APOB48R apolipoprotein B48 receptor 5.00E−06 68.1 33.9 2.01 225314_at OCIAD2 OCIA domain containing 2 5.00E−06 160.7 709.5 0.23 204359_at FLRT2 fibronectin leucine rich 5.00E−06 259.5 36.6 7.09 transmembrane protein 2 229686_at P2RY8 purinergic receptor P2Y, G-protein 5.00E−06 72.5 33.3 2.18 coupled, 8 221215_s_at RIPK4 receptor-interacting serine-threonine 5.00E−06 47.5 169.1 0.28 kinase 4 208981_at PECAM1 platelet/endothelial cell adhesion 5.00E−06 440.2 134.3 3.28 molecule (CD31 antigen) 204265_s_at GPSM3 G-protein signalling modulator 3 6.00E−06 370.9 141 2.63 (AGS3-like, C. elegans) 223303_at URP2 UNC-112 related protein 2 6.00E−06 294.1 83.2 3.53 205504_at BTK Bruton agammaglobulinemia tyrosine 6.00E−06 126.9 48.5 2.62 kinase 228931_at 6.00E−06 48.2 135.6 0.36 210784_x_at LILRB2/ leukocyte immunoglobulin-like 6.00E−06 191.6 109.3 1.75 LILRB3 receptor, subfamily B (with TM and ITIM domains), member 2/leukocyte immunoglobulin-like receptor, subfamily B (with TM and ITIM domains), member 3 214574_x_at LST1 leukocyte specific transcript 1 6.00E−06 213.9 71.9 2.97 230925_at APBB1IP amyloid beta (A4) precursor protein- 6.00E−06 661 167.2 3.95 binding, family B, member 1 interacting protein 204192_at CD37 CD37 molecule 6.00E−06 104.9 19.2 5.46 206868_at STARD8 START domain containing 8 6.00E−06 99 57.6 1.72 229367_s_at GIMAP6 GTPase, IMAP family member 6 6.00E−06 136.7 33 4.14 203957_at E2F6 E2F transcription factor 6 7.00E−06 63.2 148.9 0.42 230805_at Transcribed locus, strongly similar to 6.00E−06 71 35.6 1.99 XP_511906.1 PREDICTED: similar to KIAA0612 protein [Pan troglodytes] 205400_at WAS Wiskott-Aldrich syndrome (eczema- 7.00E−06 52 27.8 1.87 thrombocytopenia) 38964_r_at WAS Wiskott-Aldrich syndrome (eczema- 7.00E−06 394.8 239.5 1.65 thrombocytopenia) 204674_at LRMP lymphoid-restricted membrane 7.00E−06 135.4 56 2.42 protein 211654_x_at HLA-DQB1 major histocompatibility complex, 7.00E−06 476.5 121.6 3.92 class II, DQ beta 1 226879_at HVCN1 hydrogen voltage-gated channel 1 7.00E−06 127.3 65.9 1.93 203622_s_at LOC56902 putatative 28 kDa protein 7.00E−06 128 297.5 0.43 204957_at ORC5L origin recognition complex, subunit 5- 7.00E−06 88 194.2 0.45 like (yeast) 209199_s_at MEF2C MADS box transcription enhancer 7.00E−06 561.9 79.6 7.06 factor 2, polypeptide C (myocyte enhancer factor 2C) 216218_s_at PLCL2 phospholipase C-like 2 7.00E−06 34 10.8 3.15 227419_x_at PLAC9 placenta-specific 9 7.00E−06 179.3 58.5 3.06 213603_s_at RAC2 ras-related C3 botulinum toxin 8.00E−06 1278.7 247.4 5.17 substrate 2 (rho family, small GTP binding protein Rac2) 209447_at SYNE1 spectrin repeat containing, nuclear 8.00E−06 171.8 38.9 4.42 envelope 1 219452_at DPEP2 dipeptidase 2 8.00E−06 49.7 22.2 2.24 232676_x_at MYEF2 myelin expression factor 2 8.00E−06 82.2 228.8 0.36 200807_s_at HSPD1 heat shock 60 kDa protein 1 8.00E−06 2153.1 4492.3 0.48 (chaperonin) 219183_s_at PSCD4 pleckstrin homology, Sec7 and 8.00E−06 152.8 67.1 2.28 coiled-coil domains 4 236517_at MEGF10 multiple EGF-like-domains 10 9.00E−06 30.3 8.4 3.61 224451_x_at ARHGAP9 Rho GTPase activating protein 9 9.00E−06 270.3 65.5 4.13 218708_at NXT1 NTF2-like export factor 1 9.00E−06 121.4 253.2 0.48 211135_x_at LILRB2/ leukocyte immunoglobulin-like 9.00E−06 185.8 109.8 1.69 LILRB3 receptor, subfamily B (with TM and ITIM domains), member 2/leukocyte immunoglobulin-like receptor, subfamily B (with TM and ITIM domains), member 3 224929_at LOC340061 hypothetical protein LOC340061 1.00E−05 182.1 74.3 2.45 204628_s_at ITGB3 integrin, beta 3 (platelet glycoprotein 1.00E−05 45.1 24.7 1.83 IIIa, antigen CD61) 230413_s_at AP1S2 Adaptor-related protein complex 1, 1.00E−05 37.5 15.2 2.47 sigma 2 subunit 205644_s_at SNRPG small nuclear ribonucleoprotein 1.00E−05 1079.8 2300.1 0.47 polypeptide G 219947_at CLEC4A C-type lectin domain family 4, 1.00E−05 70.1 19.8 3.54 member A 1598_g_at GAS6 growth arrest-specific 6  1.1e−05 625.7 245.8 2.55 209716_at CSF1 colony stimulating factor 1  1.1e−05 204.5 110.6 1.85 (macrophage) 219191_s_at BIN2 bridging integrator 2  1.1e−05 237 64.5 3.67 226673_at SH2D3C SH2 domain containing 3C  1.1e−05 87.7 46.2 1.90 213715_s_at ANKRD47 ankyrin repeat domain 47  1.2e−05 67.3 39.4 1.71 222771_s_at MYEF2 myelin expression factor 2  1.1e−05 27.2 84.1 0.32 1552316_a_at GIMAP1 GTPase, IMAP family member 1  1.2e−05 62.8 18.5 3.39 220765_s_at LIMS2 LIM and senescent cell antigen-like  1.2e−05 116 71.7 1.62 domains 2 230264_s_at AP1S2 adaptor-related protein complex 1,  1.2e−05 761 153.1 4.97 sigma 2 subunit 208335_s_at DARC Duffy blood group, chemokine  1.4e−05 108.4 30.2 3.59 receptor 204852_s_at PTPN7 protein tyrosine phosphatase, non-  1.4e−05 64.7 27.1 2.39 receptor type 7 202911_at MSH6 mutS homolog 6 (E. coli)  1.5e−05 203.1 370.6 0.55 228376_at GGTA1 Glycoprotein, alpha-  1.5e−05 278.7 72.8 3.83 galactosyltransferase 1 235359_at LRRC33 leucine rich repeat containing 33  1.5e−05 93.8 33.1 2.83 32502_at GDPD5 glycerophosphodiester  1.5e−05 140 77.1 1.82 phosphodiesterase domain containing 5 209002_s_at CALCOCO1 calcium binding and coiled-coil  1.5e−05 191.5 89.7 2.13 domain 1 226863_at FAM110C Family with sequence similarity 110  1.5e−05 17.6 183.1 0.10 member C 228311_at BCL6B B-cell CLL/lymphoma 6, member B  1.5e−05 81.2 49.9 1.63 (zinc finger protein) 228339_at LOC641700 Hypothetical protein LOC641700  1.5e−05 65.4 34 1.92 1555811_at ARHGDIB Rho GDP dissociation inhibitor (GDI)  1.5e−05 141.8 92.3 1.54 beta 212793_at DAAM2 dishevelled associated activator of  1.5e−05 146.1 43 3.40 morphogenesis 2 217549_at Transcribed locus, strongly similar to  1.5e−05 90 46.2 1.95 NP_848718.1 mitochondrial ribosomal protein L50 [Mus musculus] 209354_at TNFRSF14 tumor necrosis factor receptor  1.6e−05 138.9 81.1 1.71 superfamily, member 14 (herpesvirus entry mediator) 215382_x_at TPSAB1 tryptase alpha/beta 1  1.6e−05 143.1 40 3.58 210340_s_at CSF2RA colony stimulating factor 2 receptor,  1.7e−05 27.6 16.2 1.70 alpha, low-affinity (granulocyte- macrophage) 225763_at RCSD1 RCSD domain containing 1  1.6e−05 166.3 36.3 4.58 228677_s_at FLJ21438 hypothetical protein FLJ21438  1.7e−05 131.4 75.5 1.74 244598_at LOC133874 Hypothetical gene LOC133874  1.7e−05 37.1 22.5 1.65 200696_s_at GSN gelsolin (amyloidosis, Finnish type)  1.7e−05 2017.7 659.7 3.06 203813_s_at SLIT3 slit homolog 3 (Drosophila)  1.7e−05 86.1 35.5 2.43 216033_s_at FYN FYN oncogene related to SRC, FGR,  1.7e−05 83.1 25.4 3.27 YES 207677_s_at NCF4 neutrophil cytosolic factor 4, 40 kDa  1.7e−05 96.2 17 5.66 207238_s_at PTPRC protein tyrosine phosphatase,  1.8e−05 448.9 75.6 5.94 receptor type, C 211742_s_at EVI2B ecotropic viral integration site 2B  1.8e−05 582.2 93.5 6.23 212556_at SCRIB scribbled homolog (Drosophila)  1.8e−05 104.2 305.5 0.34 228332_s_at C11orf31 chromosome 11 open reading frame  1.8e−05 755.4 1868.8 0.40 31 237563_s_at LOC440731 hypothetical LOC440731  1.8e−05 48.2 202.7 0.24 203176_s_at TFAM transcription factor A, mitochondrial  1.9e−05 30.1 68.8 0.44 220966_x_at ARPC5L actin related protein ⅔ complex,  1.8e−05 263.1 475.4 0.55 subunit 5-like 223562_at PARVG parvin, gamma  1.9e−05 139.6 63.4 2.20 216041_x_at GRN granulin 2.00E−05 1187.5 416 2.85 204249_s_at LMO2 LIM domain only 2 (rhombotin-like 1)  2.1e−05 381.4 96.7 3.94 51176_at CRSP8 cofactor required for Sp1 2.00E−05 96.6 181 0.53 transcriptional activation, subunit 8, 34 kDa 1557228_at EHBP1L1 EH domain binding protein 1-like 1  2.1e−05 112.4 68.2 1.65 218460_at HEATR2 HEAT repeat containing 2  2.1e−05 182.5 366.4 0.50 205147_x_at NCF4 neutrophil cytosolic factor 4, 40 kDa  2.1e−05 87 23.2 3.75 228424_at NAALADL1 N-acetylated alpha-linked acidic  2.1e−05 70.9 42 1.69 dipeptidase-like 1 200678_x_at GRN granulin  2.2e−05 1213.4 436.3 2.78 203331_s_at INPP5D inositol polyphosphate-5-  2.2e−05 34.5 17.6 1.96 phosphatase, 145 kDa 207339_s_at LTB lymphotoxin beta (TNF superfamily,  2.2e−05 126.8 68.6 1.85 member 3) 233252_s_at STRBP spermatid perinuclear RNA binding  2.2e−05 33.5 100.9 0.33 protein 45749_at FAM65A family with sequence similarity 65,  2.2e−05 458.7 298.3 1.54 member A 203865_s_at ADARB1 adenosine deaminase, RNA-specific,  2.2e−05 151 43.3 3.49 B1 (RED1 homolog rat) 218999_at TMEM140 transmembrane protein 140  2.3e−05 208.3 86.5 2.41 221080_s_at DENND1C DENN/MADD domain containing 1C  2.3e−05 111.6 64 1.74 203103_s_at PRPF19 PRP19/PSO4 pre-mRNA processing  2.3e−05 209.6 392.9 0.53 factor 19 homolog (S. cerevisiae) 203332_s_at INPP5D inositol polyphosphate-5-  2.3e−05 165.2 69.6 2.37 phosphatase, 145 kDa 205467_at CASP10 caspase 10, apoptosis-related  2.3e−05 65.2 39.8 1.64 cysteine peptidase 227371_at BAIAP2L1 BAI1-associated protein 2-like 1  2.4e−05 28 83.7 0.33 238638_at SLC37A2 solute carrier family 37 (glycerol-3-  2.3e−05 66.1 30.9 2.14 phosphate transporter), member 2 238905_at RHOJ ras homolog gene family, member J  2.3e−05 41.6 27 1.54 212885_at MPHOSPH10 M-phase phosphoprotein 10 (U3  2.4e−05 140.5 230.1 0.61 small nucleolar ribonucleoprotein) 204228_at PPIH peptidylprolyl isomerase H  2.4e−05 181.6 360.7 0.50 (cyclophilin H) 204346_s_at RASSF1 Ras association (RalGDS/AF-6)  2.4e−05 70.8 34.8 2.03 domain family 1 211284_s_at GRN granulin  2.4e−05 813.4 316.6 2.57 217948_at  2.4e−05 83.7 158.2 0.53 223640_at HCST hematopoietic cell signal transducer  2.5e−05 204.1 74.1 2.75 1559584_a_at C16orf54 chromosome 16 open reading frame  2.5e−05 31.6 8.5 3.72 54 211781_x_at  2.5e−05 43.3 28.2 1.54 220161_s_at EPB41L4B erythrocyte membrane protein band  2.5e−05 51 306.5 0.17 4.1 like 4B 35974_at LRMP lymphoid-restricted membrane  2.5e−05 39 17.2 2.27 protein 201721_s_at LAPTM5 lysosomal associated multispanning  2.6e−05 1823.2 278.4 6.55 membrane protein 5 205277_at PRDM2 PR domain containing 2, with ZNF  2.6e−05 48.4 28.5 1.70 domain 226632_at CYGB cytoglobin  2.6e−05 126.8 34.6 3.66 226996_at LYCAT lysocardiolipin acyltransferase  2.6e−05 120.3 288.5 0.42 204638_at ACP5 acid phosphatase 5, tartrate resistant  2.7e−05 695.6 131.7 5.28 210659_at CMKLR1 chemokine-like receptor 1  2.8e−05 29.4 18.8 1.56 1294_at UBE1L ubiquitin-activating enzyme E1-like  2.8e−05 142.5 76.4 1.87 203668_at MAN2C1 mannosidase, alpha, class 2C,  2.8e−05 53 27.8 1.91 member 1 205611_at TNFSF12 tumor necrosis factor (ligand)  2.8e−05 81.7 45.2 1.81 superfamily, member 12 215380_s_at C7orf24 chromosome 7 open reading frame  2.8e−05 450.4 1424.9 0.32 24 227520_at Cxorf15 chromosome X open reading frame  2.8e−05 63.2 184.2 0.34 15 228899_at CUL1 Cullin 1  2.9e−05 37.6 132.4 0.28 204790_at SMAD7 SMAD, mothers against DPP  2.9e−05 212.7 61.6 3.45 homolog 7 (Drosophila) 205718_at ITGB7 integrin, beta 7 3.00E−05 105.4 65 1.62 221087_s_at APOL3 apolipoprotein L, 3 3.00E−05 126 58.4 2.16 201121_s_at PGRMC1 progesterone receptor membrane  3.1e−05 540.9 1149.9 0.47 component 1 217848_s_at PPA1 pyrophosphatase (inorganic) 1  3.1e−05 1169.5 2990.1 0.39 202933_s_at YES1 v-yes-1 Yamaguchi sarcoma viral  3.2e−05 139.8 508.3 0.28 oncogene homolog 1 202995_s_at FBLN1 fibulin 1  3.2e−05 271.4 35.7 7.60 209280_at MRC2 mannose receptor, C type 2  3.2e−05 209.1 109 1.92 202009_at PTK9L PTK9L protein tyrosine kinase 9-like  3.3e−05 110.5 63 1.75 (A6-related protein) 200785_s_at LRP1 low density lipoprotein-related protein  3.4e−05 191.5 80.1 2.39 1 (alpha-2-macroglobulin receptor) 203426_s_at IGFBP5 insulin-like growth factor binding  3.4e−05 57.9 31.5 1.84 protein 5 207134_x_at TPSAB1 tryptase alpha/beta 1  3.4e−05 189.6 36.9 5.14 218882_s_at WDR3 WD repeat domain 3  3.4e−05 81.8 208 0.39 218239_s_at GTPBP4 GTP binding protein 4  3.5e−05 148.7 367.8 0.40 203425_s_at IGFBP5 insulin-like growth factor binding  3.6e−05 78.7 38 2.07 protein 5 205312_at SPI1 spleen focus forming virus (SFFV)  3.6e−05 63.2 24 2.63 proviral integration oncogene spi1 209879_at SELPLG selectin P ligand  3.6e−05 139 55.7 2.50 1554503_a_at OSCAR osteoclast-associated receptor  3.7e−05 26.5 13.5 1.96 210044_s_at LYL1 lymphoblastic □aematolo derived  3.6e−05 105.3 38.1 2.76 sequence 1 238673_at Transcribed locus  3.8e−05 18.5 122.6 0.15 209302_at POLR2H polymerase (RNA) II (DNA directed)  3.8e−05 267.8 626.8 0.43 polypeptide H 212426_s_at YWHAQ tyrosine 3-  3.9e−05 858.9 1978.5 0.43 monooxygenase/tryptophan 5- monooxygenase activation protein, theta polypeptide 212766_s_at ISG20L2 interferon stimulated exonuclease  3.9e−05 90 354 0.25 gene 20 kDa-like 2 227821_at LGI4 leucine-rich repeat LGI family,  3.9e−05 136.9 72.4 1.89 member 4 201991_s_at KIF5B kinesin family member 5B 4.00E−05 759.2 1298.7 0.58 216474_x_at TPSAB1 tryptase alpha/beta 1 4.00E−05 280.2 54.6 5.13 228541_x_at NGRN Neugrin, neurite outgrowth 4.00E−05 150.8 307.7 0.49 associated 204122_at TYROBP TYRO protein tyrosine kinase binding  4.2e−05 1090.6 210.6 5.18 protein 220751_s_at C5orf4 chromosome 5 open reading frame 4  4.1e−05 207.5 61.9 3.35 201597_at COX7A2 cytochrome c oxidase subunit VIIa  4.2e−05 1215.4 2497.4 0.49 polypeptide 2 (liver) 203186_s_at S100A4 S100 calcium binding protein A4  4.2e−05 1747.6 256.4 6.82 (calcium protein, calvasculin, metastasin, murine placental homolog) 206267_s_at MATK megakaryocyte-associated tyrosine  4.2e−05 90.1 45.7 1.97 kinase 218465_at TMEM33 transmembrane protein 33  4.2e−05 79.5 203.2 0.39 223553_s_at DOK3 docking protein 3  4.2e−05 164.7 41.3 3.99 229295_at LOC150166 hypothetical protein LOC150166  4.3e−05 191.3 75.7 2.53 228519_x_at CIRBP cold inducible RNA binding protein  4.4e−05 148.9 75.9 1.96 234299_s_at NIN ninein (GSK3B interacting protein)  4.3e−05 25.5 15.5 1.65 213381_at C10orf72 Chromosome 10 open reading frame  4.4e−05 48.5 30.3 1.60 72 204789_at FMNL1 formin-like 1  4.5e−05 101.1 54.2 1.87 236029_at FAT3 FAT tumor suppressor homolog 3  4.5e−05 64 10.8 5.93 (Drosophila) 204193_at CHKB/ choline kinase beta/carnitine  4.7e−05 263.2 141.2 1.86 CPT1B palmitoyltransferase 1B (muscle) 206055_s_at SNRPA1 small nuclear ribonucleoprotein  4.6e−05 208.5 536.2 0.39 polypeptide A′ 219243_at GIMAP4 GTPase, IMAP family member 4  4.7e−05 323.9 130 2.49 221827_at C20orf18 chromosome 20 open reading frame  4.7e−05 137.9 357.2 0.39 18 223690_at LTBP2 latent transforming growth factor beta  4.6e−05 559.4 155.4 3.60 binding protein 2 228410_at GAB3 GRB2-associated binding protein 3  4.6e−05 83.5 36.5 2.29 201468_s_at NQO1 NAD(P)H dehydrogenase, quinone 1  4.8e−05 160.5 737.6 0.22 210075_at MARCH2 membrane-associated ring finger  4.7e−05 113.2 49.2 2.30 (C3HC4) 2 213733_at MYO1F myosin IF  4.7e−05 223.2 63.3 3.53 205709_s_at CDS1 CDP-diacylglycerol synthase  4.9e−05 60.5 302.8 0.20 (phosphatidate cytidylyltransferase) 1 211056_s_at SRD5A1 steroid-5-alpha-reductase, alpha  4.8e−05 50.3 127.6 0.39 polypeptide 1 (3-oxo-5 alpha-steroid delta 4-dehydrogenase alpha 1) 231991_at C20orf160 chromosome 20 open reading frame  4.8e−05 53.2 30 1.77 160 234306_s_at SLAMF7 SLAM family member 7  4.9e−05 27.8 16.7 1.66 202666_s_at ACTL6A actin-like 6A 5.00E−05 132.3 425 0.31 236583_at ABP1 Amiloride binding protein 1 (amine 5.00E−05 45.7 26 1.76 oxidase (copper-containing)) 201558_at RAE1 RAE1 RNA export 1 homolog (S. Pombe)  5.1e−05 251.1 607.1 0.41 209348_s_at MAF v-maf musculoaponeurotic  5.2e−05 499.3 150.5 3.32 fibrosarcoma oncogene homolog (avian) 219689_at SEMA3G sema domain, immunoglobulin  5.2e−05 148.3 53.2 2.79 domain (Ig), short basic domain, secreted, (□aematologi) 3G 220005_at P2RY13 purinergic receptor P2Y, G-protein  5.2e−05 62.6 14.7 4.26 coupled, 13 241227_at  5.2e−05 55.1 34.5 1.60 218606_at ZDHHC7 zinc finger, DHHC-type containing 7  5.3e−05 480.4 317.8 1.51 213541_s_at ERG v-ets erythroblastosis virus E26  5.4e−05 51.9 21.2 2.45 oncogene like (avian) 227779_at LOC641700 Hypothetical protein LOC641700  5.4e−05 30.2 18.4 1.64 201540_at FHL1 four and a half LIM domains 1  5.6e−05 1551.7 177.8 8.73 206682_at CLEC10A C-type lectin domain family 10,  5.8e−05 50.7 28.3 1.79 member A 53968_at INTS5 integrator complex subunit 5  5.7e−05 66.4 159.2 0.42 59375_at MYO15B myosin XVB pseudogene  5.8e−05 75.5 40.6 1.86 214450_at CTSW cathepsin W (lymphopain)  5.8e−05 86.9 42.6 2.04 222218_s_at PILRA paired immunoglobin-like type 2  5.8e−05 111.9 43.1 2.60 receptor alpha 222396_at HN1 □aematological and neurological  5.8e−05 116.5 268.9 0.43 expressed 1 235849_at SCARA5 scavenger receptor class A, member  5.9e−05 147.6 48.4 3.05 5 (putative) 241742_at PRAM1 PML-RARA regulated adaptor  5.9e−05 68.4 23.7 2.89 molecule 1 202735_at EBP emopamil binding protein (sterol 6.00E−05 143.9 238.8 0.60 isomerase) 207697_x_at LILRB2 leukocyte immunoglobulin-like  6.1e−05 107.8 45.7 2.36 receptor, subfamily B (with TM and ITIM domains), member 2 210569_s_at SIGLEC9 sialic acid binding Ig-like lectin 9  5.9e−05 28.9 18.7 1.55 227159_at LGP1 homolog of mouse LGP1  5.9e−05 82.3 50.2 1.64 209549_s_at DGUOK deoxyguanosine kinase  6.2e−05 260.4 466.9 0.56 214005_at GGCX gamma-glutamyl carboxylase  6.2e−05 56.6 160.8 0.35 235907_at Transcribed locus  6.1e−05 39.6 117.9 0.34 203281_s_at UBE1L ubiquitin-activating enzyme E1-like  6.4e−05 181.1 80.4 2.25 222742_s_at RABL5 RAB, member RAS oncogene family-  6.4e−05 187.5 404.5 0.46 like 5 229941_at  6.4e−05 43.1 26.6 1.62 205883_at ZBTB16 zinc finger and BTB domain  6.6e−05 42.3 18.2 2.32 containing 16 210084_x_at TPSAB1 tryptase alpha/beta 1  6.6e−05 177.3 41.8 4.24 223096_at NOP5/NOP58 nucleolar protein NOP5/NOP58  6.6e−05 528.3 1218.9 0.43 200953_s_at CCND2 cyclin D2  6.8e−05 175.6 50 3.51 209582_s_at CD200 CD200 molecule  6.8e−05 31.2 13.2 2.36 232164_s_at EPPK1 epiplakin 1  6.7e−05 30 294.4 0.10 220320_at DOK3 docking protein 3 7.00E−05 47.2 26.2 1.80 1558828_s_at DKFZp586C0721 Hypothetical protein 7.00E−05 51.5 21.4 2.41 DKFZp586C0721 201326_at CCT6A chaperonin containing TCP1, subunit  7.1e−05 255.7 537.7 0.48 6A (zeta 1) 228139_at RIPK3 receptor-interacting serine-threonine  7.1e−05 51.6 28.7 1.80 kinase 3 38149_at ARHGAP25 Rho GTPase activating protein 25  7.1e−05 110 42.9 2.56 201040_at GNAI2 guanine nucleotide binding protein (G  7.2e−05 291.3 150.2 1.94 protein), alpha inhibiting activity polypeptide 2 211800_s_at USP4 ubiquitin specific peptidase 4 (proto-  7.2e−05 208.6 107.8 1.94 oncogene) 222056_s_at FAHD2A fumarylacetoacetate hydrolase  7.3e−05 77.8 164.4 0.47 domain containing 2A 225381_at LOC399959 hypothetical gene supported by  7.2e−05 65.4 16.2 4.04 BX647608 229491_at LOC133308 hypothetical protein BC009732  7.2e−05 104.7 30.2 3.47 237324_s_at HKDC1 hexokinase domain containing 1  7.2e−05 26 16.3 1.60 202877_s_at CD93 CD93 molecule  7.4e−05 124.3 50.5 2.46 225543_at GTF3C4 General transcription factor IIIC,  7.5e−05 44.5 107.1 0.42 polypeptide 4, 90 kDa 229041_s_at ITGB2 Integrin, beta 2 (complement  7.5e−05 90.3 31.5 2.87 component 3 receptor 3 and 4 subunit) 204256_at ELOVL6 ELOVL family member 6, elongation  7.6e−05 28.4 87.8 0.32 of long chain fatty acids (FEN1/Elo2, SUR4/Elo3-like, yeast) 209651_at TGFB1I1 transforming growth factor beta 1  7.6e−05 160.9 59.9 2.69 induced transcript 1 229121_at CDNA FLJ44441 fis, clone  7.7e−05 85.7 39.7 2.16 UTERU2020242 200058_s_at ASCC3L1 activating signal cointegrator 1  7.8e−05 548.2 989.7 0.55 complex subunit 3-like 1 205418_at FES feline sarcoma oncogene  7.9e−05 69.8 38.3 1.82 207741_x_at TPSAB1/ tryptase alpha/beta 1/tryptase beta 2  7.7e−05 131.2 43.6 3.01 TPSB2 209948_at KCNMB1 potassium large conductance  7.8e−05 76 36.4 2.09 calcium-activated channel, subfamily M, beta member 1 218434_s_at AACS acetoacetyl-CoA synthetase  7.8e−05 93.1 225 0.41 1553155_x_at ATP6V0D2 ATPase, H+ transporting, lysosomal 8.00E−05 32.5 16.5 1.97 38 kDa, V0 subunit d2 213309_at PLCL2 phospholipase C-like 2 8.00E−05 90.2 32 2.82 212281_s_at TMEM97 transmembrane protein 97  8.2e−05 55 292.1 0.19 219347_at NUDT15 nudix (nucleoside diphosphate linked  8.1e−05 27.9 90.6 0.31 moiety X)-type motif 15 242402_x_at  8.2e−05 59.5 38.8 1.53 201089_at ATP6V1B2 ATPase, H+ transporting, lysosomal  8.4e−05 629.6 191.4 3.29 56/58 kDa, V1 subunit B2 203119_at CCDC86 coiled-coil domain containing 86  8.6e−05 71.1 127.4 0.56 217249_x_at  8.5e−05 252.2 511.7 0.49 228477_at FLJ10154 Hypothetical protein FLJ10154  8.5e−05 395.2 219.3 1.80 227557_at SCARF2 scavenger receptor class F, member 2  8.8e−05 59.1 35.8 1.65 203300_x_at AP1S2 adaptor-related protein complex 1, 9.00E−05 408.4 108.7 3.76 sigma 2 subunit 209583_s_at CD200 CD200 molecule  8.9e−05 178.5 57.9 3.08 226187_at CDS1 CDP-diacylglycerol synthase 9.00E−05 41.6 141.5 0.29 (phosphatidate cytidylyltransferase) 1 204223_at PRELP proline/arginine-rich end leucine-rich  9.2e−05 336.1 92.1 3.65 repeat protein 205377_s_at ACHE acetylcholinesterase (Yt blood group)  9.1e−05 36.9 17.2 2.15 210299_s_at FHL1 four and a half LIM domains 1  9.2e−05 476.2 34.6 13.76 235306_at GIMAP8 GTPase, IMAP family member 8  9.2e−05 113.6 32.1 3.54 212390_at PDE4DIP phosphodiesterase 4D interacting  9.4e−05 480.5 69.5 6.91 protein (myomegalin) 213915_at NKG7 natural killer cell group 7 sequence  9.5e−05 94.6 24.5 3.86 225372_at C10orf54 chromosome 10 open reading frame  9.3e−05 39.4 20.8 1.89 54 232922_s_at C20orf59 chromosome 20 open reading frame  9.3e−05 55.1 33.9 1.63 59 203175_at RHOG ras homolog gene family, member G  9.7e−05 385.2 181.5 2.12 (rho G) 219282_s_at TRPV2 transient receptor potential cation  9.6e−05 92 35.8 2.57 channel, subfamily V, member 2 222010_at TCP1 t-complex 1  9.7^(e)−05 67.9 166.8 0.41 227156_at TNRC8 trinucleotide repeat containing 8  9.7e−05 30.5 117.2 0.26 221246_x_at TNS1 tensin 1  9.9e−05 253.4 138.5 1.83 224677_x_at C11orf31 chromosome 11 open reading frame  9.9e−05 452.7 742.4 0.61 31 LUNG METASTASIS ASSOCIATED MARKERS Geometric mean of intensities in ratio Gene Parametric p- Lung Non_Lung Probe Set Symbol Gene Title value metastases metastases 204751_x_at DSC2 desmocollin 2 p < 0.000001 249.1 30.4 8.19 235651_at p < 0.000001 158.3 16.4 9.65 223861_at HORMAD1 HORMA domain containing 1 2.00E−06 219.7 10.2 21.54 228171_s_at PLEKHG4 pleckstrin homology domain 2.00E−06 109.5 40.5 2.70 containing, family G (with RhoGef domain) member 4 228577_x_at ODF2L outer dense fiber of sperm tails 2-like 8.00E−06 44.3 15.3 2.90 220941_s_at C21orf91 chromosome 21 open reading frame 1.00E−05 96.2 26.7 3.60 91 227642_at TFCP2L1 Transcription factor CP2-like 1 1.00E−05 278.2 50.6 5.50 229523_at TTMA Two transmembrane domain family 1.30E−05 73.6 20.1 3.66 member A 219867_at CHODL chondrolectin 1.40E−05 49.2 17.3 2.84 205428_s_at CALB2 calbindin 2, 29 kDa (calretinin) 1.60E−05 327.4 35.6 9.20 228956_at UGT8 UDP glycosyltransferase 8 (UDP- 1.80E−05 191.1 12.4 15.41 galactose ceramide galactosyltransferase) 227452_at LOC146795 Hypothetical protein LOC146795 1.80E−05 139.4 25.8 5.40 1554246_at C1orf210 chromosome 1 open reading frame 2.10E−05 45.4 19.9 2.28 210 221705_s_at SIKE suppressor of IKK epsilon 2.10E−05 30.6 16.5 1.85 211488_s_at ITGB8 integrin, beta 8 2.60E−05 25.5 14.7 1.73 213372_at PAQR3 progestin and adipoQ receptor family 2.90E−05 322.5 57.2 5.64 member III 208103_s_at ANP32E acidic (leucine-rich) nuclear 3.20E−05 333.7 55.7 5.99 phosphoprotein 32 family, member E 60474_at KIND1 chromosome 20 open reading frame 3.60E−05 113.3 16.5 6.87 42 222869_s_at ELAC1 elaC homolog 1 (E. coli) 3.60E−05 38 23.3 1.63 227829_at GYLTL1B glycosyltransferase-like 1B 3.90E−05 187.1 70.9 2.64 231033_at Full length insert cDNA clone 3.90E−05 71.9 16.6 4.33 YI40A07 226075_at SPSB1 splA/ryanodine receptor domain and 5.60E−05 92.3 31.9 2.89 SOCS box containing 1 214596_at CHRM3 cholinergic receptor, muscarinic 3 6.10E−05 38 18.8 2.02 225363_at PTEN Phosphatase and tensin homolog 6.20E−05 235.3 569.9 0.41 (mutated in multiple advanced cancers 1) 242488_at CDNA FLJ38396 fis, clone 6.20E−05 60.2 19 3.17 FEBRA2007957 213889_at PIGL phosphatidylinositol glycan, class L 6.60E−05 37.9 21.2 1.79 1553705_a_at CHRM3 cholinergic receptor, muscarinic 3 7.00E−05 30.8 16.7 1.84 203256_at CDH3 cadherin 3, type 1, P-cadherin 9.50E−05 252.2 41.4 6.09 (placental) LIVER METASTASIS ASSOCIATED MARKERS Geometric mean of intensities in ratio Gene Parametric p- Liver Non_Liver Probe Set Symbol Gene Title value metastases metastases 239847_at CDNA clone IMAGE: 6186815 p < 0.000001 107 24.7 4.33 219682_s_at TBX3 T-box 3 (ulnar mammary syndrome) p < 0.000001 515.5 45.4 11.35 225544_at TBX3 T-box 3 (ulnar mammary syndrome) p < 0.000001 345.6 57.2 6.04 229053_at SYT17 Synaptotagmin XVII p < 0.000001 142.6 17.9 7.97 221823_at LOC90355 hypothetical gene supported by p < 0.000001 420.5 91.6 4.59 AF038182; BC009203 221008_s_at AGXT2L1 alanine-glyoxylate aminotransferase 0.000001 30.6 8.3 3.69 2-like 1 1557415_s_at LETM2 leucine zipper-EF-hand containing 0.000001 27.1 14.5 1.87 transmembrane protein 2 1558881_at LOC145820 hypothetical protein LOC145820 0.000001 25.7 14.6 1.76 228718_at ZNF44 zinc finger protein 44 0.000002 48.9 16.7 2.93 219115_s_at IL20RA interleukin 20 receptor, alpha 0.000002 63 15.8 3.99 226344_at ZMAT1 zinc finger, matrin type 1 0.000003 144 36.6 3.93 214156_at MYRIP myosin VIIA and Rab interacting 0.000003 37 12 3.08 protein 218173_s_at WHSC1L1 Wolf-Hirschhorn syndrome candidate 0.000003 80.5 21.5 3.74 1-like 1 225561_at SELT selenoprotein T 0.000003 436.3 107.6 4.05 238496_at WHSC1L1 Wolf-Hirschhorn syndrome candidate 0.000003 135.3 37.6 3.60 1-like 1 209710_at GATA2 GATA binding protein 2 0.000003 367.9 80.5 4.57 239638_at CDNA FLJ33227 fis, clone 0.000004 44 17.6 2.50 ASTRO2001088 207988_s_at ARPC2 actin related protein ⅔ complex, 0.000005 600 1062.5 0.56 subunit 2, 34 kDa 225915_at CAB39L calcium binding protein 39-like 0.000006 130.3 23.3 5.59 217691_x_at SLC16A3 solute carrier family 16 0.000006 66.9 145.6 0.46 (monocarboxylic acid transporters), member 3 235675_at DHFRL1 dihydrofolate reductase-like 1 0.000007 76.5 18.9 4.05 229908_s_at CDNA: FLJ21189 fis, clone 0.000007 142.6 77.9 1.83 CAS11887 1556308_at PRRT3 proline-rich transmembrane protein 3 0.000007 173.4 44.7 3.88 242981_at CYP3A5 Cytochrome P450, family 3, 0.000007 57 29 1.97 subfamily A, polypeptide 5 204635_at RPS6KA5 ribosomal protein S6 kinase, 90 kDa, 0.000008 145 52.7 2.75 polypeptide 5 227091_at KIAA1505 KIAA1505 protein 0.000008 91.8 36.7 2.50 239859_x_at ATP5S ATP synthase, H+ transporting, 0.000008 42.4 24.5 1.73 mitochondrial F0 complex, subunit s (factor B) 1555982_at ZFYVE16 Zinc finger, FYVE domain containing 0.000009 77.4 19.5 3.97 16 213118_at KIAA0701 KIAA0701 protein 0.000009 165.6 59.4 2.79 230570_at Transcribed locus 0.000009 95.4 22.8 4.18 236117_at Transcribed locus 0.000009 49.6 19.5 2.54 237083_at Transcribed locus 0.000009 26.6 11.3 2.35 210825_s_at PEBP1 phosphatidylethanolamine binding 0.00001 4026.3 1903.1 2.12 protein 1 238719_at Transcribed locus 0.00001 92.6 48.8 1.90 225318_at DDHD2 DDHD domain containing 2 0.000012 489.1 139.8 3.50 212637_s_at WWP1 WW domain containing E3 ubiquitin 0.000012 291.8 45 6.48 protein ligase 1 229602_at Transcribed locus 0.000013 45.3 21.1 2.15 222312_s_at CDNA clone IMAGE: 6186815 0.000014 143.7 53.3 2.70 1555827_at CCNL1 Cyclin L1 0.000014 33 15.7 2.10 226766_at ROBO2 roundabout, axon guidance receptor, 0.000015 27.8 10.1 2.75 homolog 2 (Drosophila) 244749_at FAM111B Family with sequence similarity 111, 0.000015 34.5 13.3 2.59 member B 212209_at THRAP2 thyroid hormone receptor associated 0.000017 391.1 157.1 2.49 protein 2 204349_at CRSP9 cofactor required for Sp1 0.000017 119.4 61.5 1.94 transcriptional activation, subunit 9, 33 kDa 217191_x_at 0.000019 50.4 23.6 2.14 227582_at KARCA1 kelch/ankyrin repeat containing cyclin 0.00002 305.1 81.6 3.74 A1 interacting protein 231069_at Transcribed locus 0.00002 76 18.3 4.15 202856_s_at SLC16A3 solute carrier family 16 0.000021 39.1 244.6 0.16 (monocarboxylic acid transporters), member 3 224076_s_at WHSC1L1 Wolf-Hirschhorn syndrome candidate 0.000022 293.1 84.4 3.47 1-like 1 230141_at ARID4A AT rich interactive domain 4A (RBP1- 0.000024 59.2 25.3 2.34 like) 204045_at TCEAL1 transcription elongation factor A (SII)- 0.000025 638.9 179.6 3.56 like 1 212425_at SCAMP1 Secretory carrier membrane protein 1 0.000025 72.9 31.5 2.31 242366_at KIAA0701 KIAA0701 protein 0.000025 127.8 52.6 2.43 213757_at EIF5A Eukaryotic translation initiation factor 0.000027 194.8 467.4 0.42 5A 228039_at DDX46G DEAD (Asp-Glu-Ala-Asp) box 0.000027 205.3 82.2 2.50 polypeptide 46 205420_at PEX7 peroxisomal biogenesis factor 7 0.000031 101.9 34.3 2.97 204633_s_at RPS6KA5 ribosomal protein S6 kinase, 90 kDa, 0.000032 252.3 88.5 2.85 polypeptide 5 225606_at BCL2L11 BCL2-like 11 (apoptosis facilitator) 0.000032 399.4 187.5 2.13 208628_s_at YBX1 Y box binding protein 1 0.000033 849.7 2307.6 0.37 239437_at Transcribed locus 0.000033 66.6 22.6 2.95 208760_at UBE2I Ubiquitin-conjugating enzyme E2I 0.000034 275.1 97.5 2.82 (UBC9 homolog, yeast) 223989_s_at REXO2 REX2, RNA exonuclease 2 homolog 0.000034 60.4 95 0.64 (S. cerevisiae) 225557_at AXUD1 AXIN1 up-regulated 1 0.000035 159.4 74 2.15 1563189_at CDNA: FLJ20907 fis, clone 0.000036 38.4 17.5 2.19 ADSE00408 223126_s_at C1orf21 chromosome 1 open reading frame 0.000036 226.4 63 3.59 21 1553719_s_at ZNF548 zinc finger protein 548 0.000037 45.9 17.7 2.59 227641_at FBXL16 F-box and leucine-rich repeat protein 0.000038 524.3 92.9 5.64 16 1558345_a_at LOC439911 hypothetical gene supported by 0.000039 93.4 32.3 2.89 NM_194304 1563629_a_at LOC283874 hypothetical protein LOC283874 0.000041 72.7 34.5 2.11 231820_x_at ZNF587 zinc finger protein 587 0.000041 57.2 22.5 2.54 218692_at FLJ20366 hypothetical protein FLJ20366 0.000042 407.2 59.3 6.87 235048_at KIAA0888 KIAA0888 protein 0.000044 99.8 24.9 4.01 1555848_at MRNA full length insert cDNA clone 0.000045 87.2 50.6 1.72 EUROIMAGE 1652049 228189_at BAG4 BCL2-associated athanogene 4 0.000046 648.4 138.6 4.68 200757_s_at CALU calumenin 0.000049 264.5 444.8 0.59 228768_at KIAA1961 KIAA1961 gene 0.000052 312.1 142.2 2.19 227572_at USP30 Ubiquitin specific peptidase 30 0.000054 237.6 115.1 2.06 237086_at 0.000055 168.6 18.9 8.92 204622_x_at NR4A2 nuclear receptor subfamily 4, group 0.000056 192.4 38.1 5.05 A, member 2 204667_at FOXA1 forkhead box A1 0.000055 431.6 41.9 10.30 231472_at FBXO15 F-box protein 15 0.000055 79.2 31.6 2.51 229158_at WNK4 WNK lysine deficient protein kinase 4 0.00006 80.1 22.8 3.51 1558279_a_at CDNA FLJ36555 fis, clone 0.000061 27.7 12.2 2.27 TRACH2008716 201253_s_at CDIPT CDP-diacylglycerol--inositol 3- 0.000061 1517.7 776.4 1.95 phosphatidyltransferase (phosphatidylinositol synthase) 214053_at Clone 23736 mRNA sequence 0.000061 198.4 26 7.63 228328_at CDNA FLJ33653 fis, clone 0.000061 138 53.4 2.58 BRAMY2024715 224477_s_at NUDT16L1 nudix (nucleoside diphosphate linked 0.000063 144.7 73.2 1.98 moiety X)-type motif 16-like 1 225223_at SMAD5 SMAD, mothers against DPP 0.000063 276.3 103.4 2.67 homolog 5 (Drosophila) 237706_at STXBP4 Syntaxin binding protein 4 0.000063 27.1 10.8 2.51 1556666_a_at TTC6 tetratricopeptide repeat domain 6 0.000064 50.3 10.5 4.79 242140_at LOC113386 similar to envelope protein 0.000066 350.7 73.2 4.79 1556665_at TTC6 tetratricopeptide repeat domain 6 0.000068 44.3 17.5 2.53 1560648_s_at TSPYL1 TSPY-like 1 0.000068 27.5 12.5 2.20 229069_at CIP29 cytokine induced protein 29 kDa 0.000069 81 43 1.88 204024_at C8orf1 chromosome 8 open reading frame 1 0.000071 54.1 19 2.85 221248_s_at WHSC1L1 Wolf-Hirschhorn syndrome candidate 0.000073 30.4 17.3 1.76 1-like 1 227332_at Full-length cDNA clone 0.000074 52.8 24.8 2.13 CS0DD005YE10 of Neuroblastoma Cot 50-normalized of Homo sapiens (human) 238005_s_at Transcribed locus 0.000074 115.6 49 2.36 242245_at SYDE2 Synapse defective 1, Rho GTPase, 0.000075 133.2 22.2 6.00 homolog 2 (C. elegans) 239024_at SLC12A8 Solute carrier family 12 0.000077 68.2 27.3 2.50 (potassium/chloride transporters), member 8 223605_at SLC25A18 solute carrier family 25 (mitochondrial 0.000079 39.7 17 2.34 carrier), member 18 229167_at Full-length cDNA clone 0.000079 94.8 51.2 1.85 CS0DF014YA22 of Fetal brain of Homo sapiens (human) 202992_at C7 complement component 7 0.000086 365.4 46.7 7.82 204226_at STAU2 staufen, RNA binding protein, 0.000085 404.1 110.7 3.65 homolog 2 (Drosophila) 240557_at TSC22D2 TSC22 domain family, member 2 0.000086 40.7 19.8 2.06 204121_at GADD45G growth arrest and DNA-damage- 0.000087 81.3 37.1 2.19 inducible, gamma 217954_s_at PHF3 PHD finger protein 3 0.000087 476.1 251 1.90 239329_at Transcribed locus 0.000088 78.3 35.3 2.22 222820_at TNRC6C trinucleotide repeat containing 6C 0.000089 219.1 54.3 4.03 227279_at TCEAL3 transcription elongation factor A (SII)- 0.000089 848.7 306.3 2.77 like 3 242139_s_at LOC113386 similar to envelope protein 0.000092 366.7 98.8 3.71 222204_s_at RRN3 RRN3 RNA polymerase I 0.000097 340.4 125.2 2.72 transcription factor homolog (S. cerevisiae) 224876_at C5orf24 chromosome 5 open reading frame 0.000097 870.5 444.3 1.96 24 226115_at AHCTF1 AT hook containing transcription 0.000097 218 81.1 2.69 factor 1 233198_at LOC92497 hypothetical protein LOC92497 0.000099 159.4 57.4 2.78 BRAIN METASTASIS ASSOCIATED MARKERS Geometric mean of intensities in ratio Gene Parametric p- Brain Non_Brain Probe Set Symbol Gene Title value Metastases Metastases 1559822_s_at LOC644215 Hypothetical protein LOC644215 p < 0.000001 321.4 111.7 2.88 212384_at BAT1 HLA-B associated transcript 1 p < 0.000001 37.5 16.7 2.25 236946_at GPR75 G protein-coupled receptor 75 p < 0.000001 36.4 19 1.92 213483_at PPWD1 peptidylprolyl isomerase domain and p < 0.000001 34.8 110.9 0.31 WD repeat containing 1 217631_at p < 0.000001 29.6 15.2 1.95 210141_s_at INHA inhibin, alpha p < 0.000001 27.1 17.4 1.56 235596_at Transcribed locus p < 0.000001 40.8 23.3 1.75 203131_at PDGFRA platelet-derived growth factor p < 0.000001 23.1 378.2 0.06 receptor, alpha polypeptide 226100_at MLL5 myeloid/lymphoid or mixed-lineage p < 0.000001 36.8 110.5 0.33 leukemia 5 (trithorax homolog, Drosophila) 231457_at Transcribed locus, strongly similar to 1.00E−06 53.4 35 1.53 NP_116090.2 suppressor of variegation 4-20 homolog 2 [Homo sapiens] 200926_at RPS23 ribosomal protein S23 1.00E−06 5022.1 8620.6 0.58 224694_at ANTXR1 anthrax toxin receptor 1 1.00E−06 63.5 464.8 0.14 235984_at 2.00E−06 71.9 27.1 2.65 224797_at ARRDC3 arrestin domain containing 3 2.00E−06 35.4 205.6 0.17 239121_at PTK2 PTK2 protein tyrosine kinase 2 2.00E−06 32.4 20.1 1.61 244804_at SQSTM1 Sequestosome 1 3.00E−06 98.1 38.8 2.53 207761_s_at METTL7A methyltransferase like 7A 3.00E−06 149.8 1011.8 0.15 223408_s_at 4.00E−06 56.2 29.7 1.89 235410_at NPHP3 nephronophthisis 3 (adolescent) 4.00E−06 28.5 123 0.23 214154_s_at PKP2 plakophilin 2 4.00E−06 38.2 25.4 1.50 236210_at DDX31 DEAD (Asp-Glu-Ala-Asp) box 5.00E−06 51.9 23.6 2.20 polypeptide 31 225572_at FAM119A Family with sequence similarity 119, 5.00E−06 80.4 151 0.53 member A 1558154_at LLGL2 Lethal giant larvae homolog 2 5.00E−06 35.6 18.4 1.93 (Drosophila) 221780_s_at DDX27 DEAD (Asp-Glu-Ala-Asp) box 6.00E−06 402.7 159.8 2.52 polypeptide 27 226839_at TRA16 TR4 orphan receptor associated 6.00E−06 187.1 78.4 2.39 protein TRA16 209844_at HOXB13 homeobox B13 6.00E−06 45.7 25.2 1.81 229274_at GNAS GNAS complex locus 6.00E−06 34 15.1 2.25 220072_at CSPP1 centrosome and spindle pole 7.00E−06 40.1 22.5 1.78 associated protein 1 226237_at COLBA1 Collagen, type VIII, alpha 1 8.00E−06 24.7 368.2 0.07 220965_s_at RSHL1 radial spokehead-like 1 9.00E−06 76.4 46.7 1.64 213865_at DCBLD2 discoidin, CUB and LCCL domain 9.00E−06 27.7 14.6 1.90 containing 2 212106_at UBXD8 UBX domain containing 8 9.00E−06 175.9 76.7 2.29 205224_at SURF2 surfeit 2 1.00E−05 95.2 55.7 1.71 225945_at ZNF655 zinc finger protein 655 1.00E−05 54.6 351.2 0.16 206103_at RAC3 ras-related C3 botulinum toxin 1.00E−05 33 17.5 1.89 substrate 3 (rho family, small GTP binding protein Rac3) 209837_at AP4M1 adaptor-related protein complex 4,  1.1e−05 36.4 23.4 1.56 mu 1 subunit 213069_at HEG1 HEG homolog 1 (zebrafish)  1.1e−05 61.3 273.5 0.22 229467_at PCBP2 Poly(rC) binding protein 2  1.1e−05 149.8 57.2 2.62 235432_at NPHP3 nephronophthisis 3 (adolescent)  1.2e−05 13.5 36.6 0.37 239596_at SLC30A7 solute carrier family 30 (zinc  1.3e−05 34.1 17.9 1.91 transporter), member 7 233091_at ATAD3A/ ATPase family, AAA domain  1.4e−05 45.2 29.5 1.53 ATAD3B containing 3A/ATPase family, AAA domain containing 3B 216546_s_at CHI3L1 chitinase 3-like 1 (cartilage  1.4e−05 38.4 24.8 1.55 glycoprotein-39) 1565666_s_at MUC6 mucin 6, oligomeric mucus/gel-  1.5e−05 107 13.4 7.99 forming 210719_s_at HMG20B high-mobility group 20B  1.5e−05 674 127.9 5.27 203796_s_at BCL7A B-cell CLL/lymphoma 7A  1.6e−05 72.2 35.6 2.03 244305_at GGN gametogenetin  1.5e−05 49.8 30.1 1.65 241668_s_at  1.6e−05 30.8 17.7 1.74 218501_at ARHGEF3 Rho guanine nucleotide exchange  1.7e−05 75.8 283.5 0.27 factor (GEF) 3 200897_s_at PALLD palladin, cytoskeletal associated  1.8e−05 247.4 998.9 0.25 protein 208900_s_at TOP1 topoisomerase (DNA) I  1.8e−05 104.4 30.1 3.47 208823_s_at PCTK1 PCTAIRE protein kinase 1  1.9e−05 192.7 105.8 1.82 234654_at C20orf4 Chromosome 20 open reading frame 4 2.00E−05 27.6 17.5 1.58 213376_at ZBTB1 zinc finger and BTB domain 2.00E−05 42.7 143.4 0.30 containing 1 229699_at CDNA FLJ45384 fis, clone  2.1e−05 25.9 75.5 0.34 BRHIP3021987 240148_at MSH6 MutS homolog 6 (E. coli) 2.00E−05 27.7 16.5 1.68 239957_at SETD5 SET domain containing 5  2.1e−05 45.6 18.6 2.45 1555778_a_at POSTN periostin, osteoblast specific factor  2.2e−05 16.7 495.4 0.03 206141_at MOCS3 molybdenum cofactor synthesis 3  2.1e−05 71.4 38 1.88 227428_at GABPA GA binding protein transcription  2.2e−05 21 39.1 0.54 factor, alpha subunit 60 kDa 223607_x_at ZSWIM1 zinc finger, SWIM-type containing 1  2.3e−05 130 82.9 1.57 219050_s_at ZNHIT2 zinc finger, HIT type 2  2.4e−05 83.5 50.5 1.65 236700_at LOC653352 similar to eukaryotic translation  2.3e−05 28.5 12.4 2.30 initiation factor 3, subunit 8 204095_s_at ELL e elongation factor RNA  2.4e−05 67.9 38.2 1.78 polymrase II 217817_at ARPC4 actin related protein ⅔ complex,  2.4e−05 650.6 194 3.35 subunit 4, 20 kDa 215887_at ZNF277 zinc finger protein 277  2.4e−05 116.6 61 1.91 205537_s_at VAV2 vav 2 oncogene  2.5e−05 43.9 27.5 1.60 210110_x_at HNRPH3 heterogeneous nuclear  2.6e−05 68.1 157.2 0.43 ribonucleoprotein H3 (2H9) 206230_at LHX1 LIM homeobox 1  2.6e−05 52.4 25.8 2.03 238741_at FAM83A family with sequence similarity 83,  2.9e−05 85.3 42.2 2.02 member A 242970_at DIP2B DIP2 disco-interacting protein 2  2.9e−05 35.6 19.9 1.79 homolog B (Drosophila) 215089_s_at RBM10 RNA binding motif protein 10  3.1e−05 284.5 160.7 1.77 212088_at PMPCA peptidase (mitochondrial processing)  3.1e−05 221.1 127.4 1.74 alpha 225877_at TYSND1 trypsin domain containing 1  3.1e−05 92.7 37.4 2.48 237257_at RAB4B RAB4B, member RAS oncogene  3.4e−05 135.8 77 1.76 family 224822_at DLC1 deleted in liver cancer 1  3.4e−05 46.7 133 0.35 227433_at KIAA2018 KIAA2018  3.4e−05 43 146.6 0.29 244870_at TES testis derived transcript (3 LIM  3.5e−05 35 22.8 1.54 domains) 226157_at TFDP2 Transcription factor Dp-2 (E2F  3.7e−05 40.5 105.1 0.39 dimerization partner 2) 224023_s_at C3orf10 chromosome 3 open reading frame  3.7e−05 59.8 31.7 1.89 10 225512_at ZBTB38 zinc finger and BTB domain  3.9e−05 62.9 257.4 0.24 containing 38 238738_at PSMD7 Proteasome (prosome, macropain)  3.9e−05 49.9 29.4 1.70 26S subunit, non-ATPase, 7 (Mov34 homolog) 205407_at RECK reversion-inducing-cysteine-rich  4.1e−05 10.6 43.6 0.24 protein with kazal motifs 221763_at JMJD1C jumonji domain containing 1C  4.1e−05 77.7 234.7 0.33 229439_s_at FLJ20273 RNA-binding protein  4.1e−05 111.6 66.3 1.68 212437_at CENPB centromere protein B, 80 kDa  4.3e−05 203.4 117.7 1.73 244374_at PLAC2 placenta-specific 2  4.3e−05 59.1 39.4 1.50 212179_at C6orf111 chromosome 6 open reading frame  4.4e−05 92.3 287.6 0.32 111 213238_at ATP10D ATPase, Class V, type 10D  4.4e−05 25.9 94.9 0.27 223886_s_at RNF146 ring finger protein 146  4.7e−05 108.8 295.9 0.37 230557_at XRRA1 X-ray radiation resistance associated 1  4.8e−05 33.9 20.2 1.68 205460_at NPAS2 neuronal PAS domain protein 2  5.1e−05 31.8 18.6 1.71 223954_x_at APBA2BP amyloid beta (A4) precursor protein-  5.3e−05 126.6 62.8 2.02 binding, family A, member 2 binding protein 224715_at WDR34 WD repeat domain 34  5.3e−05 383.8 130.3 2.95 206875_s_at SLK STE20-like kinase (yeast)  5.4e−05 104.1 314.6 0.33 242935_at SBF2 SET binding factor 2  5.4e−05 42.5 27.1 1.57 210588_x_at HNRPH3 heterogeneous nuclear  5.4e−05 141.1 311.8 0.45 ribonucleoprotein H3 (2H9) 201086_x_at SON SON DNA binding protein  5.8e−05 318.9 689.4 0.46 213000_at MORC3 MORC family CW-type zinc finger 3  5.7e−05 48.6 119.1 0.41 209285_s_at C3orf63 chromosome 3 open reading frame  5.9e−05 31.9 87.3 0.37 63 213891_s_at CDNA FLJ37747 fis, clone  5.8e−05 100 435.7 0.23 BRHIP2022986 225898_at WDR54 WD repeat domain 54  5.9e−05 322 131.1 2.46 212632_at STX7 Syntaxin 7  6.1e−05 72.6 173.3 0.42 225050_at ZNF512 zinc finger protein 512 6.00E−05 48.5 130.1 0.37 213233_s_at KLHL9 kelch-like 9 (Drosophila)  6.2e−05 135.5 428.4 0.32 1556316_s_at LOC284889 hypothetical protein LOC284889  6.4e−05 122.2 34.1 3.58 211603_s_at ETV4 ets variant gene 4 (E1A enhancer  6.5e−05 116.2 61 1.90 binding protein, E1AF) 213297_at RMND5B required for meiotic nuclear division 5  6.6e−05 81.5 49.8 1.64 homolog B (S. cerevisiae) 218694_at ARMCX1 armadillo repeat containing, X-linked 1  6.6e−05 35.1 234.3 0.15 227281_at SLC29A4 solute carrier family 29 (nucleoside 6.7e−05 83.6 46.3 1.81 transporters), member 4 1555788_a_at TRIB3 tribbles homolog 3 (Drosophila)  7.3e−05 49.8 20.3 2.45 206076_at LRRC23 leucine rich repeat containing 23  7.4e−05 54.4 28.3 1.92 209383_at DDIT3 DNA-damage-inducible transcript 3  7.4e−05 470 182.4 2.58 225730_s_at THUMPD3 THUMP domain containing 3  7.5e−05 70 29.7 2.36 241478_at MICAL-L2 MICAL-like 2  7.4e−05 102 64.6 1.58 208676_s_at PA2G4 proliferation-associated 2G4, 38 kDa  7.5e−05 650.8 267.7 2.43 241402_at TSEN54 tRNA splicing endonuclease 54  7.6e−05 72.7 47.1 1.54 homolog (S. cerevisiae) 208117_s_at LAS1L LAS1-like (S. cerevisiae)  7.8e−05 312.5 190 1.64 218061_at MEA1 male-enhanced antigen 1  7.8e−05 1100.1 583.2 1.89 218370_s_at S100PBP S100P binding protein  7.8e−05 56.7 118.6 0.48 204413_at TRAF2 TNF receptor-associated factor 2  7.9e−05 81 51.4 1.58 228307_at EMILIN3 elastin microfibril interfacer 3  8.2e−05 58.8 31.2 1.88 228334_x_at KIAA1712 KIAA1712  8.1e−05 30.3 92.6 0.33 208880_s_at PRPF6 PRP6 pre-mRNA processing factor 6  8.6e−05 429.3 156.1 2.75 homolog (S. cerevisiae) 212615_at CHD9 Chromodomain helicase DNA binding  8.5e−05 56.9 185.4 0.31 protein 9 201643_x_at JMJD1B jumonji domain containing 1B 9.00E−05 160.1 298.1 0.54 236781_at ANKS1A Ankyrin repeat and sterile alpha motif 9.00E−05 35.9 22.4 1.60 domain containing 1A 205166_at CAPN5 calpain 5  9.1e−05 27.1 16.3 1.66 225838_at EPC2 enhancer of polycomb homolog 2  9.1e−05 71.1 194.1 0.37 (Drosophila) 1553778_at WBSCR27 Williams Beuren syndrome  9.5e−05 67.4 42.3 1.59 chromosome region 27 217200_x_at CYB561 cytochrome b-561  9.6e−05 416.8 191.8 2.17 206124_s_at LLGL1 lethal giant larvae homolog 1  9.8e−05 45.1 28.5 1.58 (Drosophila) 232264_at EDD1 E3 ubiquitin protein ligase, HECT  9.9e−05 98 31.8 3.08 domain containing, 1 241743_at  9.8e−05 39.6 24.2 1.64

TABLE 2 Organ specific Gene Parametric Gene Ontology Biological relapses Probe set symbol Description p-value ratio process and pathway BONE 221724_s_at CLEC4A C-type lectin domain family 4, member A p < 1e−07 2.45 immune response 204153_s_at MFNG manic fringe homolog (Drosophila) p < 1e−07 2.69 Notch signaling pathway 208922_s_at NXF1 nuclear RNA export factor 1 p < 1e−07 1.61 mRNA processing 227002_at FAM78A family with sequence similarity 78, member A p < 1e−07 2.43 226245_at KCTD1 potassium channel tetramerisation domain containing 1 1.00E−07 0.30 potassium ion transport 227372_s_at BAIAP2L1 BAI1-associated protein 2-like 1 1.00E−07 0.10 206060_s_at PTPN22 protein tyrosine phosphatase, non-receptor type 22 1.00E−07 4.12 signal transduction (lymphoid) 232523_at MEGF10 MEGF10 protein 1.00E−07 10.77 222392_x_at PERP PERP, TP53 apoptosis effector 1.00E−07 0.09 regulation of apoptosis 211178_s_at PSTPIP1 proline-serine-threonine phosphatase interacting protein 1 2.00E−07 3.01 cell adhesion 204236_at FLI1 Friend leukemia virus integration 1 2.00E−07 4.80 regulation of transcription 213290_at COL6A2 collagen, type VI, alpha 2 2.00E−07 2.63 extracellular matrix organization 203547_at CD4 CD4 antigen (p55) 2.00E−07 2.62 immune response 205382_s_at CFD complement factor D (adipsin) 2.00E−07 7.37 immune response 235593_at ZFHX1B zinc finger homeobox 1b 2.00E−07 2.92 regulation of transcription 206120_at CD33 CD33 antigen (gp67) 3.00E−07 2.33 cell adhesion 219091_s_at MMRN2 multimerin 2 4.00E−07 2.96 214181_x_at LST1 leukocyte specific transcript 1 4.00E−07 3.87 immune response 1552667_a_at SH2D3C SH2 domain containing 3C 5.00E−07 2.31 intracellular signalling cascade 205326_at RAMP3 receptor (calcitonin) activity modifying protein 3 5.00E−07 1.95 protein transport LUNG 204751_x_at DSC2 desmocollin 2 p < 8.19 cell adhesion 0.000001 223861_at HORMAD1 HORMA domain containing 1 2.00E−06 21.54 228171_s_at PLEKHG4 pleckstrin homology domain containing, family G (with 2.00E−06 2.70 regulation of Rho protein RhoGef domain) member 4 signal transduction 228577_x_at ODF2L outer dense fiber of sperm tails 2-like 8.00E−06 2.90 220941_s_at C21orf91 chromosome 21 open reading frame 91 1.00E−05 3.60 227642_at TFCP2L1 Transcription factor CP2-like 1 1.00E−05 5.50 regulation of transcription 219867_at CHODL chondrolectin 1.40E−05 2.84 205428_s_at CALB2 calbindin 2, 29 kDa (calretinin) 1.60E−05 9.20 calcium ion binding 228956_at UGT8 UDP glycosyltransferase 8 1.80E−05 15.41 nervous system development 1554246_at C1orf210 chromosome 1 open reading frame 210 2.10E−05 2.28 221705_s_at SIKE suppressor of IKK epsilon 2.10E−05 1.85 211488_s_at ITGB8 integrin, beta 8 2.60E−05 1.73 cell-matrix adhesion 213372_at PAQR3 progestin and adipoQ receptor family member III 2.90E−05 5.64 208103_s_at ANP32E acidic (leucine-rich) nuclear phosphoprotein 32 family, 3.20E−05 5.99 regulation of synaptogenesis member E 60474_at KIND1 Kindlin 1 3.60E−05 6.87 cell adhesion 222869_s_at ELAC1 elaC homolog 1 (E. coli) 3.60E−05 1.63 regulation of transcription 227829_at GYLTL1B glycosyltransferase-like 1B 3.90E−05 2.64 synaptic transmission 226075_at SPSB1 splA/ryanodine receptor domain and SOCS box 5.60E−05 2.89 intracellular signalling containing 1 cascade 225363_at PTEN Phosphatase and tensin homolog (mutated in multiple 6.20E−05 0.41 regulation of cell advanced cancers 1) proliferation/migration 1553705_a_at CHRM3 cholinergic receptor, muscarinic 3 7.00E−05 1.84 signal transduction LIVER 219682_s_at TBX3 T-box 3 (ulnar mammary syndrome) 1.00E−07 11.35 regulation of transcription 221823_at C5orf30 Chromosome 5 open reading frame 30 1.00E−06 4.59 221008_s_at AGXT2L1 alanine-glyoxylate aminotransferase 2-like 1  1.1e−06 3.69 amino acid metabolism 1557415_s_at LETM2 Leucine zipper-EF-hand containing transmembrane  1.2e−06 1.87 protein 2 228718_at ZNF44 zinc finger protein 44 (KOX 7)  1.9e−06 2.93 regulation of transcription 219115_s_at IL20RA interleukin 20 receptor, alpha  2.3e−06 3.99 blood coagulation 226344_at ZMAT1 zinc finger, matrin type 1  2.6e−06 3.93 nucleotide biosynthesis 214156_at MYRIP myosin VIIA and Rab interacting protein  2.8e−06 3.08 intracellular protein transport 218173_s_at WHSC1L1 Wolf-Hirschhorn syndrome candidate 1-like 1  2.9e−06 3.74 regulation of transcription 225561_at SELT selenoprotein T 3.00E−06 4.05 cell redox homeostasis 209710_at GATA2 GATA binding protein 2  3.3e−06 4.57 regulation of transcription 235675_at DHFRL1 dihydrofolate reductase-like 1 7.00E−06 4.05 nucleotide biosynthesis 207988_s_at ARPC2 actin related protein 2/3 complex, subunit 2, 34 kDa 5.00E−06 0.56 cell motility 217691_x_at SLC16A3 solute carrier family 16 (monocarboxylic acid transporters), 6.00E−06 0.46 transport member 3 229908_s_at GNPTG N-acetylglucosamine-1-phosphate transferase, gamma 7.00E−06 1.83 lysosome subunit 1556308_at PRRT3 proline-rich transmembrane protein 3 7.00E−06 3.88 204635_at RPS6KA5 ribosomal protein S6 kinase, 90 kDa, polypeptide 5 8.00E−06 2.75 regulation of transcription 227091_at KIAA1505 KIAA1505 protein 8.00E−06 2.50 1555982_at ZFYVE16 Zinc finger, FYVE domain containing 16 9.00E−06 3.97 regulation of endocytosis 213118_at KIAA0701 KIAA0701 protein 9.00E−06 2.79 BRAIN 213483_at PPWD1 peptidylprolyl isomerase domain and WD repeat 4.00E−07 0.31 protein folding containing 1 210141_s_at INHA inhibin, alpha 4.00E−07 1.56 cytokine 203131_at PDGFRA platelet-derived growth factor receptor, alpha polypeptide 5.00E−07 0.06 signal transduction 226100_at MLL5 myeloid/lymphoid or mixed-lineage leukemia 5 7.00E−07 0.33 regulation of transcription 200926_at RPS23 ribosomal protein S23 1.40E−06 0.58 protein biosynthesis 224694_at ANTXR1 anthrax toxin receptor 1 1.50E−06 0.14 224797_at ARRDC3 arrestin domain containing 3 1.70E−06 0.17 207761_s_at METTL7A methyltransferase like 7A 3.20E−06 0.15 235410_at NPHP3 nephronophthisis 3 (adolescent) 3.70E−06 0.23 kinesin complex 214154_s_at PKP2 plakophilin 2 3.90E−06 1.50 cell adhesion 221780_s_at DDX27 DEAD (Asp-Glu-Ala-Asp) box polypeptide 27 5.60E−06 2.52 226839_at TRA16 TR4 orphan receptor associated protein TRA16 5.90E−06 2.39 signal transduction 209844_at HOXB13 homeo box B13 6.40E−06 1.81 regulation of transcription 220072_at CSPP1 centrosome and spindle pole associated protein 1 6.50E−06 1.78 microtuble organization 220965_s_at RSHL1 radial spokehead-like 1 8.50E−06 1.64 iron homeostasis 213865_at DCBLD2 discoidin, CUB and LCCL domain containing 2 9.00E−06 1.90 cell adhesion/wound healing 212106_at UBXD8 UBX domain containing 8 9.00E−06 2.29 205224_at SURF2 surfeit 2 1.00E−05 1.71 225945_at ZNF655 zinc finger protein 655 1.00E−05 0.16 regulation of transcription 206103_at RAC3 ras-related C3 botulinum toxin substrate 3 1.00E−05 1.89 signal transduction

TABLE 3 mean of relative esperssion in Organ- Primers (5′->3′) other specific Gene SEQ ID SEQ specific metastases p relapses symbol Forward N^(o) Reverse N^(o) metastases ratio value BONE KCTD1 AAA TAC CCT GAA TCC 1 TGC TGT TTG AGA CTG 2 0.47 0.76 0.62 0.0894 AGA ATC GGA A TCCAAA ACA AT BAIAP2L1 AGA CCG CGG CTC CTA 3 AGT CGG GCG GAG TTT 4 0.93 2.08 0.45 0.0250 ACG AT CAC AGT PERP CTG TGG TGG AAA TGC 5 GCT GCT CTA CCC CAC 6 0.34 2.36 0.14 0.0018 TCC CAA GA GCG TAC T CFD ACA GCC AGC CCG ACA 7 TGG CCT TCT CCG ACA 8 2.03 0.22 9.18 0.0012 CCA T GCT GTA CD4 GTA CAG CTT CCC AGA 9 CAT TCA GCT TGG ATG 10 7.82 2.09 3.74 0.0022 AGA AGA GCA TA GAC CTT TAG T COL6A2 GAA ACA ACA ACT GCC CAG 11 CCG AGG TGT CCA GCA 12 1.35 1.03 1.30 0.0073 AGA AGA CGA A FLI1 CCT CAG TTA CCT CAG 13 GGT CGG TGT GGG AGG 14 2.67 0.34 7.81 0.0007 GGA AAG TTC A TTG TAT TAT PSTPIP1 CAA GAG TTT GAC CGG 15 CCG CAC TTC CTC GTA 16 5.02 0.84 5.95 0.0018 CTG ACC AT GAG CTC AT MEGF10 TGC ACG CGG CAC AGA 17 CCC GCT TTC ATA AAA 18 19.45 0.77 25.26 0.0011 GTC A TCC AGG ACA PTPN22 ACC ATG GAA AAT TCA 19 GTT TCG CAA AAT TTT 20 10.14 1.72 5.90 0.0012 ACA TCT TCA A CAA ACT CTT ACT FAM78A AGC CAC ATG GAG TTC 21 AGT CGC TGA TGG CTT 22 6.74 1.47 4.59 0.0022 TAC AAC CAG T GGA TCT T NXF1 CGA CGT CAA TTC CTT 23 GAA AAA CAC AGC AAT 24 1.53 0.66 2.31 0.0018 CGT GGT A GTG CTT GTC T MFNG CCA GGA CCA GGG AAC 25 CGG AGC AGT TGG TGA 26 1.88 0.62 3.04 0.0056 AGA CAT T CCA CA CLEC4A CAC CAT ACA ATG AAA 27 GGG TGA TTT ACG AAA 28 5.26 0.67 7.91 0.0009 GTT CCA CAT TCT ATT TAG CAC AA LUNG KIND1 AAG GAA CTT GAA CAA 29 GGC ACA ACT TCG CAG 30 4.77 1.08 4.41 0.0404 GGA GAA CCA CT CCT CTA ELAC1 AAA GCC AAC TTA AAG CAG 31 AGC CCA GGA AGG CCA 32 0.85 0.67 1.27 0.2220 GGA GAA T AAG AA ANP32E TTT TGA ACT ACT GCA GCA 33 TCA TCT TCA TCG CCA 34 3.84 1.69 2.28 0.0168 AAT CAC A TCC TCA T PAQR3 TCG AAG ATG GAT GGC ATT 35 CAA GTA CAC CTG ACG 36 4.01 1.67 2.41 0.1440 AGA TTA T CCA GTA GTT AT ITGB8 GAC TGG GCC AAG GTG AAG 37 CCT CTT GAA CAC ACC 38 1.13 0.20 5.67 0.0054 ACA ATC CAC ATT C1orf210 GAG GCT GAG ACT CAC 39 CGA AGG CCC AAC AAG 40 1.59 0.99 1.61 0.0797 TGG TGT CAT TGT TTT SIKE CTTGCAACAGGAAAACAG 41 CTG TTT CCG ATA TTT 42 1.22 1.10 1.11 0.7500 AGAGCTA GCT CAT GAT AA UGT8 AAA GGC ATG GGG ATA 43 CCC TCT GAC GGT AGC 44 3.40 0.36 9.59 0.0021 TTG CTA GAA TGG GAT CALB2 GAA AGG CTC TGG CAT 45 CTG CCA TCT CGA TTT 46 17.30 1.32 13.11 0.1073 GAT GTC AA TCC CAT CT CHODL CTG GAT AGG GCT TTG 47 TTC ATC TGT GTA CCA 48 3.17 0.49 6.51 0.1432 GAG GAA GTT TCG GTA CT C21orf91 AAG AAA CAC TCT CCT 49 ATC AGA CTT TGG TAC 50 1.06 0.94 1.12 0.9150 TCT GCC ACA T CCC CTC AAT TFCP2L1 CAG TGG CTT CAC CGC 51 TTC AGC AAG TCA GCA 52 2.19 0.29 7.70 0.0005 AAC A CCT GAG A ODF2L CAA ACA AAG GCT TGA 53 GTT TCA GAC AAC TTG 54 1.65 1.42 1.16 1.0000 CCA TTT TAC A GCT TCC TGA T HORMAD1 CAA CAT GAA TCT GGG 55 TCC TTT TTG GCA CTG 56 153.90 1.60 96.19 0.0025 AGA ATA GTC CT ACT CTT GA PLEKHG4 GGT CTC CGC TGT CCC 57 GAT CTC TGA GTC CTC 58 0.61 0.32 1.91 0.2427 CTG TA AGC AGT CAA A DSC2 AAT CAA AGT TTT CAG 59 CGT ACA TGT TCT CCC 60 1.48 0.43 3.41 0.0318 AAG CCT GGA TA TCC TTG GT LIVER GATA2 CAC GAC TAC AGC AGC 61 CAC TCC CGG CCT TCT 62 4.25 2.62 1.62 0.0239 GGA CTC TT GAA CA SELT CTG CTC AAG TTC CAG 63 ATT CTC TCC TTC AAT 64 3.00 2.40 1.25 0.0801 ATT TGT GTT T GCG GAT GT WHSC1L1 TAC TAA AAG AGG AAG 65 CCC ACC TTG GAC CAC 66 1.99 0.79 2.52 0.0062 CCC CAG TTC A ACA AGA MYRIP CCA CGA CAA TCC TGC 67 TCC ACT TGC TGC TCA 68 1.21 0.81 1.51 0.1117 AGA AGA TTA T CTT TTG CT ZMAT1 GCA AGG AAG TGA ACA 69 AAT CTG CAC ACT CAT 70 1.15 0.99 1.16 0.2267 TCA AAT TAA AGA A TTT GGT AAG AGT C IL20RA ACC TTC CTG TTT CCA 71 GTC ACA CAC TGG GAC 72 0.60 0.33 1.81 0.0563 TGC AAC AA CAC GTT CT ZNF44 TCA GGA GAA ATC CAA 73 CAA TAC TAT TTC GAA 74 0.98 0.68 1.45 0.1433 GGT GTG ATG T TCT GGC TTA AGG TT LETM2 126 GAC ATT TGG AAC 75 CCC CTT CCT TGG CAA 76 4.69 1.45 3.24 0.0186 CAA CAA CCT TTA TTT CAT AGXT2L1 CAG CAA CTC TGC CGG 77 CGT TGG CTT CGG ATC 78 6.57 0.79 8.3 7 0.0091 AGA AAC T CTG AAT C5orf30 GAT GCG GAG GAC CGT 79 TCT CTT CAC CTC CTG 80 2.10 1.71 1.23 0.0505 GTC A TGC ACT TCT TBX3 CCT CTG ATG AGT CCT 81 CCT CGC TGG GAC ATA 82 2.13 0.68 3.14 0.0075 CCA GTG AAC A AAT CTT TGA BRAIN PPWD1 CTGTGGGTGATGATAAAGCAAT 83 CACTGTCCAGGAAAATAGC 84 0.44 0.92 0.48 0.0260 GAA CAAGTT PDGFRA CAT TTA CAT CTA TGT 85 ATG GCA GAA TCA TCA 86 0.02 0.51 0.05 0.0030 GCC AGA CCC A TCC TCC AC MLL5 CGA ATG AAT GTC CAT 87 TCC AGG TGA ACC AGG 88 0.42 0.60 0.71 0.3 700 CCC CAG ATA CTT GCT RPS23 GGA ATC GTG CTG GAA 89 CCA TTC TTG ATC AGC 90 0.27 0.54 0.50 0.1600 AAA GTA GGA GT TGG ACC CTT A ANTXR1 ATT CCC TGA GCC GCG 91 CAA GGC ATC GAG TTT 92 0.21 0.84 0.24 0.0220 AAA TCT TCC CTT GA ARRDC3 TGGGCACGAAAGAGATGATGA 93 GAATGAGGTAGCGAGTGGT 94 0.20 0.49 0.40 0.0120 TAA GTCTGT METTL7A 127 GGT GTG CAG AGT 95 ATC CAG GAC TTG TTG 96 0.16 0.65 0.24 0.0240 GCT GAG A CCA GAA GTAA T NPHP3 GCA ATG GAG AGA GCA 97 TTC TTT GGT CTC CCT 98 0.29 0.47 0.62 0.3500 GCA ACA AAA AAT CTT GA RSHL1 CCA CTT TCA GAA GAT 99 CCA GAG GTT GGA GCG 100 0.37 0.86 0.43 0.6600 GCA GAA ATC A CAC A CSPP1 ATG CAG GAA GGT GCC 101 CAC TAG TGT CAT CTC 102 0.94 1.20 0.78 0.6800 AAA GTT TGG GCA TTC T HOXB13 GAT GTG TTG CCA GGG 103 GCC CGC TGG AGT CTG 104 34.57 14.75 2.34 0.9400 AGA ACA GAA CAA AT TRA16 TGA GTT CAG TGC TGA 105 CTG GGA GGG GCC CTG 106 2.20 1.40 1.57 0.2400 ATC GCA ACA GTC T DDX27 CCA GTG AGA GGT CCT 107 AAA GGA AGG GCT AGC 108 3.82 1.87 2.04 0.0450 GCC AAG A TCG ATA CTG TT PKP2 CAC CCG AAA GAT GCT 109 AGG GAG AGT TTC TTT 110 0.54 0.38 1.40 0.3000 GCA TGT T GGC AAT TTC A INHA GCC CGA GGA AGA GGA 111 GCC CTC TGG CAG CTG 112 3.06 3.08 0.99 0.3400 GGA TGT ACT TGT TBP TGC ACA GGA GCC AAG 113 CAC ATC ACA GCT CCC 114 AGT GAA CAC CA

TABLE 4 Gene symbol Description Exemples of Antibodies Bone metastasis associated genes CLEC4A C-type lectin domain family 4, member A Novus biologicals (ab15854); GenWay bitoech (15-288-21195) MFNG manic fringe homolog (Drosophila) (secreted Notch ligand) Abnova (H00004242-M07) NXF1 nuclear RNA export factor 1 scbt (sc-17310, sc-32319, sc-25768, sc-28377, sc-17311) FAM78A family with sequence similarity 78, member A KCTD1 potassium channel tetramerisation domain containing 1 BAIAP2L1 BAI1-associated protein 2-like 1 Abnova (H00055971-M01); MBL int. corp (M051-3) PTPN22 protein tyrosine phosphatase, non-receptor type 22 (lymphoid) Abnova (H00026191-M01); R&Dsystems (MAB3428) MEGF10 MEGF10 protein PERP TP53 apoptosis effector Novus biologicals (NB 500-231); Sigma-Aldrich (P5243); Research diagnostics (RDI-ALS24284); GenWay bitoech (18- 661-15116) PSTPIP1 proline-serine-threonine phosphatase interacting protein 1 Abnova (H00009051-M01) Osteomimetism associated genes MMP9 matrix metalloproteinase 9 (gelatinase B, 92 kDa gelatinase, NeoMarkers (RB-1539) 92 kDa type IV collagenase) IBSP integrin-binding sialoprotein (bone sialoprotein, bone Usbiological (S1013-34B) sialoprotein II) OMD osteomodulin Abnova (H00004958-A01) COMP cartilage oligomeric matrix protein AbCam (ab11056) MEPE matrix, extracellular phosphoglycoprotein with ASARM motif R&Dsystems (AF3140) (bone) Lung metastasis associated genes (highest ranking genes) DSC2 desmocollin 2 scbt (sc-34308, sc-34311, sc-34312); Progen Biotechnik (GP542, 610120); Research diagnostics (RDI-PRO610120, RDI- PROGP542); UsBiological (D3221-50) HORMAD1 HORMA domain containing 1 Abnova (H00084072-M01) PLEKHG4 pleckstrin homology domain containing, family G (with RhoGef domain) member 4 ODF2L outer dense fiber of sperm tails 2-like C21orf91 chromosome 21 open reading frame 91 TFCP2L1 Transcription factor CP2-like 1 Abcam (ab3962), Novus biological (NB 600-22), Eurogentec (24220), Imgenex (IMG-4094) CHODL chondrolectin R&Dsystems (AF2576); Abnova (H00140578-A01) CALB2 calbindin 2, 29 kDa (calretinin) Chemicon (AB5054); Usbiological (C1036-01M) UGT8 UDP glycosyltransferase 8 (UDP-galactose ceramide galactosyltransferase) C1orf210 chromosome 1 open reading frame 210 SIKE suppressor of IKK epsilon ITGB8 integrin, beta 8 Abnova (H00003696-M01, H00003696-A01); GenWay biotech (15-288-21362); sctb (sc-10817, sc-25714, sc-6638) PAQR3 progestin and adipoQ receptor family member III ANP32E acidic (leucine-rich) nuclear phosphoprotein 32 family, member GenWay biotech (A21207), UsBiological (L1238) E KIND1 kindlin Abcam (ab24152); sctb (sc-30854) ELAC1 elaC homolog 1 (E. coli) Abnova (H00055520-A01) GYLTL1B glycosyltransferase-like 1B Liver metastasis associated genes TBX3 T-box 3 (ulnar mammary syndrome) Abnova (H00006926-A01) C5orf30 hypothetical gene supported by AF038182; BC009203 AGXT2L1 alanine-glyoxylate aminotransferase 2-like 1///alanine-glyoxylate aminotransferase 2-like 1 LETM2 Leucine zipper-EF-hand containing transmembrane protein 2 ZNF44 zing finger protein 44 IL20RA interleukin 20 receptor, alpha LifeSpan biosciences (LS-C722) ZMAT1 Zinc finger, matrin type 1 MYRIP myosin VIIA and Rab interacting protein Novus Biologicals (NB 100-1278); Everest biotech Ltd (EB06023) WHSC1L1 Wolf-Hirschhorn syndrome candidate 1-like 1 Abcam (ab4514); BioCat (AP1904a-AB) SELT selenoprotein T GATA2 GATA binding protein 2 Abnova (H00002624-M01); R&Dsystems (AF2046) DHFRL1 dihydrofolate reductase-like 1 ARPC2 actin related protein 2/3 complex, subunit 2, 34 kDa SLC16A3 solute carrier family 16 (monocarboxylic acid transporters), member 3 GNPTG PRRT3 RPS6KA5 ribosomal protein S6 kinase, 90 kDa, polypeptide 5 Santa cruz (sc-2591, sc-9392, sc-25417); R&Dsystems (AF2518) Brain metastasis associated genes PPWD1 peptidylprolyl isomerase domain and WD repeat containing 1 INHA Inhibin, alpha AbCam (Ab10599) PDGFRA platelet-derived growth factor receptor, alpha polypeptide Abnova (H00005156-M01) MLL5 myeloid/lymphoid or mixed-lineage leukemia 5 (trithorax Abgent (AP6186a); Orbigen (PAB-10849) homolog, Drosophila) RPS23 ribosomal protein S23 Abnova (H00006228-A01) ANTXR1 Anthrax toxin receptor 1 AbCam (Ab21270) ARRDC3 arrestin domain containing 3 METTL7A methyltransferase like 7A NPHP3 nephronophthisis 3 (adolescent) PKP2 plakophilin 2 Novus biologicals (ab19469)

TABLE 5 Lung metastasis associated genes obtained from a class comparison of lung (n = 5) and non-lung metastases of breast cancer (n = 18) Gene Parametric Probe Set Symbol Gene Title Function/biological process Fold change p-value 204751_x_at DSC2* desmocollin 2 Cell adhesion 8.2 p < 0.000001 223861_at HORMAD1* HORMA domain containing 1 21.5 2.00E−06 228171_s_at PLEKHG4* pleckstrin homology domain containing, Rho protein signal transduction 2.7 2.00E−06 family G, member 4 228577_x_at ODF2L* outer dense fiber of sperm tails 2-like 2.9 8.00E−06 220941_s_at C21orf91* chromosome 21 open reading frame 91 3.6 1.00E−05 227642_at TFCP2L1* Transcription factor CP2-like 1 Regulation of transcription 5.5 1.00E−05 219867_at CHODL* chondrolectin Hyaluronic acid binding 2.8 1.40E−05 205428_s_at CALB2* calbindin 2, 29 kDa (calretinin) Calcium ion binding 9.2 1.60E−05 228956_at UGT8* UDP glycosyltransferase 8 Glycosphingolipid biosynthetic process 15.4 1.80E−05 1554246_at C1orf210* chromosome 1 open reading frame 210 2.3 2.10E−05 221705_s_at SIKE* suppressor of IKK epsilon 1.9 2.10E−05 211488_s_at ITGB8* integrin, beta 8 Cell adhesion/Signal transduction 1.7 2.60E−05 213372_at PAQR3* progestin and adipoQ receptor family Receptor activity 5.6 2.90E−05 member III 208103_s_at ANP32E* acidic (leucine-rich) nuclear phosphoprotein Phosphatase inhibitor activity 6.0 3.20E−05 32 family, member E 60474_at FERMT1* Fermitin family homolog 1 (drosophila) Cell adhesion 6.9 3.60E−05 222869_s_at ELAC1* elaC homolog 1 (E. coli) tRNA processing 1.6 3.60E−05 227829_at GYLTL1B glycosyltransferase-like 1B Glycosphingolipid biosynthetic process 2.6 3.90E−05 226075_at SPSB1 splA/ryanodine receptor domain and SOCS Intracellular signalling cascade 2.9 5.60E−05 box containing 1 1553705_a_at CHRM3 cholinergic receptor, muscarinic 3 G-protein coupled signal transduction 2.0 6.10E−05 225363_at PTEN Phosphatase and tensin homolog (mutated Phosphatidylinositol signalling 0.4 6.20E−05 in multiple advanced cancers 1) 203256_at CDH3 cadherin 3, type 1, P-cadherin (placental) Cell adhesion 6.1 9.50E−05 *Genes tested by qRT-PCR. Colored lines correspond to genes that were validated (Mann-Whitney U test)

TABLE 6 Association between clinical and pathological characteristics and the 6-gene classifier among 72 lymph node-negative patients treated at CRH 6-gene classification All patients High Risk group Low Risk group Characteristics (n = 72) (n = 18) (n = 54) P value* Metastases within 10 years 0.79 yes 38 (53%) 10 (56%) 28 (52%) no 34 (47%) 8 (44%) 26 (48%) Lung metastases within 10 years 0.04 yes 11 (15%) 6 (33%) 5 (9%) no 61 (85%) 12 (67%) 49 (91%) Menopausal status 0.58 Pre 18 (31%) 6 (40%) 12 (28%) Post 40 (69%) 9 (60%) 31 (72%) Macroscopic tumor size 0.59 ≦20 mm 23 (33%) 5 (28%) 18 (35%) >20 mm 47 (67%) 13 (72%) 34 (65%) SBR histological grade 0.01 I  7 (11%) 0 (0%)  7 (15%) II 37 (60%) 7 (44%) 30 (65%) III 18 (29%) 9 (56%)  9 (20%) Estrogen receptor status <0.001 Positive 44 (61%) 3 (17%) 41 (76%) Negative 28 (39%) 15 (83%) 13 (24%) Progesterone receptor 0.004 Positive 37 (51%) 4 (22%) 33 (61%) Negative 35 (49%) 14 (78%) 21 (39%) *Chi² test

TABLE 7 Multivariate analysis for lung metastasis in 721 breast cancer patients Variable Hazard Ratio 95% C.I P value 6-gene signature (pos. vs. neg.) 2.12  1.2-3.76 0.01 ER negative (yes vs. no) 1.83 1.03-3.26 0.04 Lymph node positive (yes vs. no) 0.92 0.52-1.62 0.77

TABLE 8 Highest ranking genes obtained from a class comparison of bone and nonbone metastases of breast cancer (n = 23) Probe Set Gene Gene Title Function/biological process Fold change p value 204679_at KCNK1 potassium channel, subfamily K, potassium ion transport 0.06 p < 1e−07 member 1 221724_s_at CLEC4A C-type lectin domain family 4, member A immune response/cell adhesion/signal transduction 2.45 p < 1e−07 204153_s_at MFNG manic fringe homolog (Drosophila) Notch signaling pathway 2.69 p < 1e−07 208922_s_at NXF1 nuclear RNA export factor 1 mRNA transport 1.61 p < 1e−07 206060_s_at PTPN22 protein tyrosine phosphatase, non-receptor tyrosine phosphatase activity/signal transduction 4.12 1.00E−07 type 22 222392_x_at PERP PERP, TP53 apoptosis effector cell adhesion/apoptosis 0.09 1.00E−07 211178_s_at PSTPIP1 proline-serine-threonine phosphatase cell adhesion/signal transduction 3.01 2.00E−07 interacting protein 1 204236_at FLI1 Friend leukemia virus integration 1 regulation of transcription 4.80 2.00E−07 213290_at COL6A2 collagen, type VI, alpha 2 cell adhesion/extracellular matrix organization 2.63 2.00E−07 203547_at CD4 CD4 antigen (p55) immune response/cell adhesion/signaling pathway 2.62 2.00E−07 205382_s_at CFD D component of complement (adipsin) immune response 7.37 2.00E−07

TABLE 9 Predictive analysis of the lung metastasis-specific markers on the patients cohort named EMC-344 Parametric Hazard Cox regression SD of log Gene p-value FDR Ratio coefficient intensities Probe set symbol 1 0.0011233 0.0258359 1.429 0.357 1.36 208103_s_at ANP32E 2 0.0033469 0.0384893 1.705 0.534 0.894 221505_at ANP32E 3 0.0160063 0.122715 1.347 0.298 1.172 204751_x_at DSC2 4 0.0435256 0.2502722 1.669 0.512 0.639 213372_at PAQR3 5 0.0635786 0.2512905 1.241 0.216 1.347 219867_at CHODL 6 0.0791345 0.2512905 1.361 0.308 0.855 219735_s_at TFCP2L1 7 0.0862416 0.2512905 0.693 −0.367 0.695 221705_s_at SIKE 8 0.0874054 0.2512905 1.588 0.462 0.59 219677_at SPSB1 9 0.1819305 0.4021895 1.153 0.142 1.308 205428_s_at CALB2 10 0.182647 0.4021895 0.818 −0.201 1.154 222176_at PTEN 11 0.2246446 0.4021895 0.834 −0.182 0.865 204054_at PTEN 12 0.2258217 0.4021895 0.853 −0.159 1.081 204666_s_at SIKE 13 0.2273245 0.4021895 0.761 −0.273 0.628 211711_s_at PTEN 14 0.3015296 0.4953701 1.125 0.118 1.355 60474_at C20orf42 15 0.337911 0.5128545 1.213 0.193 0.804 220941_s_at C21orf91 16 0.3616357 0.5128545 1.086 0.083 1.621 218796_at C20orf42 17 0.3790664 0.5128545 1.059 0.057 2.435 203256_at CDH3 18 0.4986762 0.6371974 1.069 0.067 1.488 208358_s_at UGT8 19 0.57957 0.7011632 0.855 −0.157 0.538 204053_x_at PTEN 20 0.6097071 0.7011632 1.046 0.045 1.737 204750_s_at DSC2 21 0.7965431 0.8593998 0.926 −0.077 0.511 204665_at SIKE 22 0.830164 0.8593998 1.037 0.036 0.918 211488_s_at ITGB8 23 0.8593998 0.8593998 1.023 0.023 1.224 205816_at ITGB8

TABLE 9 Description of the markers of Table 9 Gene Probe set symbol Description 1 208103_s_at ANP32E acidic (leucine-rich) nuclear phosphoprotein 32 family, member E 2 221505_at ANP32E acidic (leucine-rich) nuclear phosphoprotein 32 family, member E 3 204751_x_at DSC2 desmocollin 2 4 213372_at PAQR3 progestin and adipoQ receptor family member III 5 219867_at CHODL chondrolectin 6 219735_s_at TFCP2L1 transcription factor CP2-like 1 7 221705_s_at SIKE suppressor of IKK epsilon 8 219677_at SPSB1 splA/ryanodine receptor domain and SOCS box containing 1 9 205428_s_at CALB2 calbindin 2, 29 kDa (calretinin) 10 222176_at PTEN phosphatase and tensin homolog (mutated in multiple advanced cancers 1) 11 204054_at PTEN phosphatase and tensin homolog (mutated in multiple advanced cancers 1) 12 204666_s_at SIKE suppressor of IKK epsilon 13 211711_s_at PTEN phosphatase and tensin homolog (mutated in multiple advanced cancers 1) 14 60474_at C20orf42 chromosome 20 open reading frame 42 15 220941_s_at C21orf91 chromosome 21 open reading frame 91 16 218796_at C20orf42 chromosome 20 open reading frame 42 17 203256_at CDH3 cadherin 3, type 1, P-cadherin (placental) 18 208358_s_at UGT8 UDP glycosyltransferase 8 (UDP-galactose ceramide galactosyltransferase) 19 204053_x_at PTEN phosphatase and tensin homolog (mutated in multiple advanced cancers 1) 20 204750_s_at DSC2 desmocollin 2 21 204665_at SIKE suppressor of IKK epsilon 22 211488_s_at ITGB8 integrin, beta 8 23 205816_at ITGB8 integrin, beta 8

TABLE 10 Predictive analysis of the lung metastasis-specific markers on the patients cohort named MSK-82 Parametric Cox regression SD of log p-value FDR Hazard Ratio coefficient intensities Probe set Gene symbol 1 0.0003892 0.0089516 2.08 0.732 0.87 205428_s_at CALB2 2 0.0014922 0.0171603 5.219 1.652 0.332 60474_at C20orf42 3 0.0024355 0.0186722 2.107 0.745 0.877 204751_x_at DSC2 4 0.0050329 0.0289392 4.095 1.410 0.426 219677_at SPSB1 5 0.0099859 0.0459351 1.838 0.609 0.945 208103_s_at ANP32E 6 0.0121753 0.046672 3.967 1.378 0.548 204053_x_at PTEN 7 0.0180818 0.0594116 2.72 1.001 0.483 218796_at C20orf42 8 0.0492486 0.1415897 1.513 0.414 1.255 203256_at CDH3 9 0.0588468 0.1475319 1.957 0.671 0.587 219735_s_at TFCP2L1 10 0.0641443 0.1475319 3.023 1.106 0.358 204750_s_at DSC2 11 0.0775927 0.1622393 2.493 0.913 0.422 219867_at CHODL 12 0.1165306 0.2233503 2.037 0.711 0.561 211711_s_at PTEN 13 0.1297388 0.2295379 1.524 0.421 1.021 221505_at ANP32E 14 0.1614638 0.265262 2.049 0.717 0.373 213372_at PAQR3 15 0.1929821 0.2959059 5.224 1.653 0.193 204665_at SIKE 16 0.2148451 0.3088398 2.501 0.917 0.324 220941_s_at C21orf91 17 0.4649749 0.6290837 1.541 0.432 0.385 208358_s_at UGT8 18 0.5784291 0.7391039 2.4 0.875 0.163 205816_at ITGB8 19 0.6368802 0.7709602 1.543 0.434 0.24 204666_s_at SIKE 20 0.6705386 0.7711194 1.302 0.264 0.417 204054_at PTEN 21 0.7563827 0.8013443 1.474 0.388 0.218 211488_s_at ITGB8 22 0.7683003 0.8013443 1.4 0.336 0.224 221705_s_at SIKE 23 0.8013443 0.8013443 0.547 −0.603 0.118 222176_at PTEN Description of the markers of Table 10 Probe set Gene symbol Description 1 205428_s_at CALB2 calbindin 2, 29 kDa (calretinin) 2 60474_at C20orf42 chromosome 20 open reading frame 42 3 204751_x_at DSC2 desmocollin 2 4 219677_at SPSB1 sp1A/ryanodine receptor domain and SOCS box containing 1 5 208103_s_at ANP32E acidic (leucine-rich) nuclear phosphoprotein 32 family, member E 6 204053_x_at PTEN phosphatase and tensin homolog (mutated in multiple advanced cancers 1) 7 218796_at C20orf42 chromosome 20 open reading frame 42 8 203256_at CDH3 cadherin 3, type 1, P-cadherin (placental) 9 219735_s_at TFCP2L1 transcription factor CP2-like 1 10 204750_s_at DSC2 desmocollin 2 11 219867_at CHODL chondrolectin 12 211711_s_at PTEN phosphatase and tensin homolog (mutated in multiple advanced cancers 1) 13 221505_at ANP32E acidic (leucine-rich) nuclear phosphoprotein 32 family, member E 14 213372_at PAQR3 progestin and adipoQ receptor family member III 15 204665_at SIKE suppressor of IKK epsilon 16 220941_s_at C21orf91 chromosome 21 open reading frame 91 17 208358_s_at UGT8 UDP glycosyltransferase 8 (UDP-galactose ceramide galactosyltransferase) 18 205816_at ITGB8 integrin, beta 8 19 204666_s_at SIKE suppressor of IKK epsilon 20 204054_at PTEN phosphatase and tensin homolog (mutated in multiple advanced cancers 1) 21 211488_s_at ITGB8 integrin, beta 8 22 221705_s_at SIKE suppressor of IKK epsilon 23 222176_at PTEN phosphatase and tensin homolog (mutated in multiple advanced cancers 1)

TABLE 11 Predictive analysis of the lung metastasis-specific markers on the patients cohort named NKI-295 Parametric Cox regression SD of log p-value FDR Hazard Ratio coefficient intensities Unique id GB acc UG cluster Gene symbol 1 0.0108108 0.1949653 3.108 1.134 0.403 12233 NM_014553 Hs.119903 TFCP2L1 2 0.0419568 0.1949653 3.946 1.373 0.262 5151 X56807 Hs.95612 DSC2 3 0.0432328 0.1949653 0.115 −2.163 0.21 13428 Contig39922_RC Hs.86543 GYLTL1B 4 0.0450324 0.01949653 3.656 1.296 0.275 15800 Contig46362_RC Hs.119903 TFCP2L1 5 0.0528812 0.1949653 3.024 1.107 0.327 17349 Contig49790_RC Hs.95612 DSC2 6 0.0584896 0.1949653 2.259 0.815 0.372 10488 NM_007088 Hs.106857 CALB2 7 0.0686958 0.1962737 9.446 2.246 0.141 23624 NM_000740 Hs.7138 CHRM3 8 0.0907955 0.2269888 2.069 0.727 0.381 1386 NM_001740 Hs.106857 CALB2 9 0.1562884 0.3473076 3.029 1.108 0.248 4995 AL117435 Hs.188781 PLEKHG4 10 0.2539722 0.4661338 2.258 0.814 0.23 2764 NM_003360 Hs.274293 UGT8 11 0.2841824 0.4661338 0.259 −1.351 0.151 20423 NM_000314 Hs.253309 PTEN 12 0.3003186 0.4661338 2.578 0.947 0.185 19915 NM_017671 Hs.180479 C20orf42 13 0.302987 0.4661338 3.476 1.246 0.13 20151 Contig39667_RC Hs.293811 C21orf91 14 0.3494798 0.4943692 2.038 0.712 0.264 14424 AL137342 Hs.274293 UGT8 15 0.3707769 0.4943692 3.365 1.213 0.151 7655 AF131840 Hs.458389 SPSB1 16 0.4670792 0.583849 1.397 0.334 0.421 1529 NM_001793 Hs.191842 CDH3 17 0.6470609 0.7612481 2.004 0.695 0.116 18301 NM_017447 Hs.293811 C21orf91 18 0.7465434 0.8294927 0.655 −0.423 0.157 12394 Contig33904_RC Hs.283725 CHODL 19 0.8698028 0.8848604 0.765 −0.268 0.114 22398 NM_018696 Hs.47572 ELAC1 20 0.8848604 0.8848604 0.876 −0.132 0.197 24006 NM_002214 Hs.355722 ITGB8

TABLE 12 Predictive analysis of the bone metastasis-specific markers on the patients cohort named NKI-295 Parametric p- Cox regression SD of log value FDR Hazard Ratio coefficient intensities Probe set Gene symbol 1 0.0014664 0.0762528 4.082 1.407 0.443 210629_x_at LST1 2 0.0070981 0.1002536 5.055 1.620 0.32 204236_at FLI1 3 0.0095354 0.1002536 2.566 0.942 0.565 214181_x_at LST1 4 0.0104244 0.1002536 3.094 1.129 0.398 203603_s_at ZEB2 5 0.0115734 0.1002536 3.664 1.299 0.432 214574_x_at LST1 6 0.0135848 0.1002536 3.417 1.229 0.435 211582_x_at LST1 7 0.0159031 0.1002536 3.717 1.313 0.399 215633_x_at LST1 8 0.0165012 0.1002536 2.377 0.866 0.576 219892_at TM6SF1 9 0.0179101 0.1002536 1.911 0.648 0.653 219947_at CLEC4A 10 0.0197086 0.1002536 4.627 1.532 0.342 211581_x_at LST1 11 0.0212075 0.1002536 2.838 1.043 0.435 221724_s_at CLEC4A 12 0.0286492 0.1241465 7.748 2.047 0.324 201234_at ILK 13 0.0328336 0.1313344 8.671 2.160 0.25 210786_s_at FLI1 14 0.0391372 0.133966 1.46 0.378 1.247 205382_s_at CFD 15 0.0402882 0.133966 0.483 −0.728 0.94 204678_s_at KCNK1 16 0.0412203 0.133966 1.725 0.545 0.829 213125_at OLFML2B 17 0.0479453 0.1466562 1.777 0.575 0.583 205326_at RAMP3 18 0.0628825 0.1816606 0.311 −1.168 0.68 211056_s_at SRD5A1 19 0.0718102 0.1965332 2.457 0.899 0.485 213290_at COL6A2 20 0.0794813 0.2066514 0.598 −0.514 1.02 204679_at KCNK1 21 0.1353711 0.3352046 2.9 1.065 0.322 211178_s_at PSTPIP1 22 0.1495017 0.3390126 3.198 1.163 0.299 206120_at CD33 23 0.1499479 0.3390126 2.876 1.056 0.329 204153_s_at MFNG 24 0.1698972 0.3681106 1.426 0.355 0.863 202803_s_at ITGB2 25 0.1801727 0.3738658 2.869 1.054 0.28 204152_s_at MFNG 26 0.1869329 0.3738658 0.599 −0.512 0.985 204675_at SRD5A1 27 0.2215229 0.3957445 0.029 −3.540 0.11 216424_at CD4 28 0.2236087 0.3957445 0.442 −0.816 0.681 203426_s_at IGFBP5 29 0.2247289 0.3957445 0.702 −0.354 1.162 211958_at IGFBP5 30 0.2287178 0.3957445 0.465 −0.766 0.638 203424_s_at IGFBP5 31 0.2359246 0.3957445 2.613 0.960 0.334 208922_s_at NXF1 32 0.2553002 0.4137783 0.457 −0.783 0.715 210959_s_at SRD5A1 33 0.2625901 0.4137783 0.405 −0.904 0.723 207370_at IBSP 34 0.2831181 0.4330042 0.508 −0.677 0.461 220966_x_at ARPC5L 35 0.2917092 0.4333965 0.696 −0.362 1.082 203425_s_at IGFBP5 36 0.3194611 0.4610668 0.28 −1.273 0.773 204712_at WIF1 37 0.3316346 0.4610668 1.386 0.326 0.806 209156_s_at COL6A2 38 0.3369334 0.4610668 1.925 0.655 0.368 219091_s_at MMRN2 39 0.3501288 0.4668384 0.826 −0.191 1.406 217744_s_at PERP 40 0.3756809 0.4883852 0.848 −0.165 1.532 203936_s_at MMP9 41 0.4433208 0.5622605 1.464 0.381 0.51 203547_at CD4 42 0.5021384 0.6216952 2.053 0.719 0.194 208010_s_at PTPN22 43 0.5822182 0.7021499 1.511 0.413 0.371 221565_s_at FAM26B 44 0.5941268 0.7021499 0.89 −0.117 1.233 211959_at IGFBP5 45 0.633394 0.731922 1.382 0.324 0.353 206060_s_at PTPN22 46 0.662699 0.749138 1.246 0.220 0.491 205908_s_at OMD 47 0.7906842 0.8747995 0.752 −0.285 0.252 215104_at NRIP2 48 0.9126254 0.9839027 1.084 0.081 0.381 57715_at FAM26B 49 0.9310478 0.9839027 0.869 −0.140 0.171 215639_at SH2D3C 50 0.9460603 0.9839027 1.074 0.071 0.269 213783_at MFNG 51 0.976646 0.9957959 0.985 −0.015 0.558 205907_s_at OMD Description of the markers of Table 12 Probe set Gene symbol Description 1 210629_x_at LST1 leukocyte specific transcript 1 2 204236_at FLI1 Friend leukemia virus integration 1 3 214181_x_at LST1 leukocyte specific transcript 1 4 203603_s_at ZEB2 zinc finger E-box binding homeobox 2 5 214574_x_at LST1 leukocyte specific transcript 1 6 211582_x_at LST1 leukocyte specific transcript 1 7 215633_x_at LST1 leukocyte specific transcript 1 8 219892_at TM6SF1 transmembrane 6 superfamily member 1 9 219947_at CLEC4A C-type lectin domain family 4, member A 10 211581_x_at LST1 leukocyte specific transcript 1 11 221724_s_at CLEC4A C-type lectin domain family 4, member A 12 201234_at ILK integrin-linked kinase 13 210786_s_at FLI1 Friend leukemia virus integration 1 14 205382_s_at CFD complement factor D (adipsin) 15 204678_s_at KCNK1 potassium channel, subfamily K, member 1 16 213125_at OLFML2B olfactomedin-like 2B 17 205326_at RAMP3 receptor (G protein-coupled) activity modifying protein 3 18 211056_s_at SRD5A1 steroid-5-alpha-reductase, alpha polypeptide 1 (3-oxo-5 alpha-steroid delta 4-dehydrogenase alpha 1) 19 213290_at COL6A2 collagen, type VI, alpha 2 20 204679_at KCNK1 potassium channel, subfamily K, member 1 21 211178_s_at PSTPIP1 proline-serine-threonine phosphatase interacting protein 1 22 206120_at CD33 CD33 molecule 23 204153_s_at MFNG MFNG O-fucosylpeptide 3-beta-N-acetylglucosaminyltransferase 24 202803_s_at ITGB2 integrin, beta 2 (complement component 3 receptor 3 and 4 subunit) 25 204152_s_at MFNG MFNG O-fucosylpeptide 3-beta-N-acetylglucosaminyltransferase 26 204675_at SRD5A1 steroid-5-alpha-reductase, alpha polypeptide 1 (3-oxo-5 alpha-steroid delta 4-dehydrogenase alpha 1) 27 216424_at CD4 CD4 molecule 28 203426_s_at IGFBP5 insulin-like growth factor binding protein 5 29 211958_at IGFBP5 insulin-like growth factor binding protein 5 30 203424_s_at IGFBP5 insulin-like growth factor binding protein 5 31 208922_s_at NXF1 nuclear RNA export factor 1 32 210959_s_at SRD5A1 steroid-5-alpha-reductase, alpha polypeptide 1 (3-oxo-5 alpha-steroid delta 4-dehydrogenase alpha 1) 33 207370_at IBSP integrin-binding sialoprotein (bone sialoprotein, bone sialoprotein II) 34 220966_x_at ARPC5L actin related protein 2/3 complex, subunit 5-like 35 203425_s_at IGFBP5 insulin-like growth factor binding protein 5 36 204712_at WIF1 WNT inhibitory factor 1 37 209156_s_at COL6A2 collagen, type VI, alpha 2 38 219091_s_at MMRN2 multimerin 2 39 217744_s_at PERP PERP, TP53 apoptosis effector 40 203936_s_at MMP9 matrix metallopeptidase 9 (gelatinase B, 92 kDa gelatinase, 92 kDa type IV collagenase) 41 203547_at CD4 CD4 molecule 42 208010_s_at PTPN22 protein tyrosine phosphatase, non-receptor type 22 (lymphoid) 43 221565_s_at FAM26B family with sequence similarity 26, member B 44 211959_at IGFBP5 insulin-like growth factor binding protein 5 45 206060_s_at PTPN22 protein tyrosine phosphatase, non-receptor type 22 (lymphoid) 46 205908_s_at OMD osteomodulin 47 215104_at NRIP2 nuclear receptor interacting protein 2 48 57715_at FAM26B family with sequence similarity 26, member B 49 215639_at SH2D3C SH2 domain containing 3C 50 213783_at MFNG MFNG O-fucosylpeptide 3-beta-N-acetylglucosaminyltransferase 51 205907_s_at OMD osteomodulin

TABLE 13 Highest ranking genes obtained from a class comparison of bone and non-bone metastases of breast cancer (n = 23) Probe Set Gene Gene Title Fold p value 203936_s_at MMP9 matrix metallopeptidase 9 36.73 p < 1e−07 204679_at KCNK1 potassium channel, subfamily K, member 1 0.06 p < 1e−07 236028_at IBSP Integrin-binding sialoprotein (bone sialoprotein) 123.76 p < 1e−07 205907_s_at OMD osteomodulin 41.31 p < 1e−07 221724_s_at CLEC4A C-type lectin domain family 4, member A 2.45 p < 1e−07 204153_s_at MFNG manic fringe homolog (Drosophila) 2.69 p < 1e−07 57715_at FAM26B family with sequence similarity 26, member B 2.29 p < 1e−07 226914_at ARPC5L actin related protein 2/3 complex, subunit 5-like 0.35 p < 1e−07 208922_s_at NXF1 nuclear RNA export factor 1 1.61 p < 1e−07 227002_at FAM78A family with sequence similarity 78, member A 2.43 p < 1e−07 226245_at KCTD1 potassium channel tetramerisation domain containing 1 0.31 1.00E−07 227372_s_at BAIAP2L1 BAI1-associated protein 2-like 1 0.10 1.00E−07 206060_s_at PTPN22 protein tyrosine phosphatase, non-receptor type 22 4.12 1.00E−07 232523_at MEGF10 MEGF10 protein 10.78 1.00E−07 222392_x_at PERP PERP, TP53 apoptosis effector 0.09 1.00E−07 231879_at COL12A1 collagen, type XII, alpha 1 8.35 1.00E−07 211178_s_at PSTPIP1 proline-serine-threonine phosphatase interacting protein 1 3.01 2.00E−07 204236_at FLI1 Friend leukemia virus integration 1 4.80 2.00E−07 213290_at COL6A2 collagen, type VI, alpha 2 2.63 2.00E−07 203547_at CD4 CD4 antigen (p55) 2.62 2.00E−07 205382_s_at CFD D component of complement (adipsin) 7.37 2.00E−07 204712_at WIF1 WNT inhibitory factor 1 25.94 2.00E−07 235593_at ZEB2 zinc finger homeobox 1b 2.92 2.00E−07 206120_at CD33 CD33 antigen (gp67) 2.33 3.00E−07 232204_at EBF early B-cell factor 5.00 4.00E−07 219091_s_at MMRN2 multimerin 2 2.96 4.00E−07 214181_x_at LST1 leukocyte specific transcript 1 3.87 4.00E−07 211958_at IGFBP5 insulin-like growth factor binding protein 5 4.04 4.00E−07 1552667_a_at SH2D3C SH2 domain containing 3C 2.31 5.00E−07 205326_at RAMP3 receptor (calcitonin) activity modifying protein 3 1.95 5.00E−07 202803_s_at ITGB2 integrin, beta 2 (antigen CD18 (p95) 8.33 5.00E−07 201234_at ILK integrin-linked kinase 2.22 5.00E−07 227243_s_at EBF3 early B-cell factor 3 3.70 6.00E−07 219892_at TM6SF1 transmembrane 6 superfamily member 1 5.42 6.00E−07 215104_at NRIP2 nuclear receptor interacting protein 2 1.34 7.00E−07 223245_at STRBP spermatid perinuclear RNA binding protein 0.29 8.00E−07 226345_at ARL8 ADP-ribosylation factor-like 8 0.31 9.00E−07 204675_at SRD5A1 steroid-5-alpha-reductase, alpha polypeptide 1 0.15 9.00E−07 225373_at C10orf54 chromosome 10 open reading frame 54 3.10 9.00E−07 213125_at OLFML2B olfactomedin-like 2B 8.01 9.00E−07 

1-16. (canceled)
 17. An in vitro method for predicting the occurrence of lung metastasis in a patient affected with a breast cancer, comprising the steps of: a) providing a breast tumour tissue sample previously collected from the patient to be tested; b) determining, in the said breast tumour tissue sample, the expression level of one or more markers comprised in the group consisting of DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1, and c) predicting the occurrence of metastasis in the lung when one or more of the said lung-specific markers has a deregulated expression level, as compared to a control expression level value for each marker.
 18. The method according to claim 17, wherein the control expression level value for each marker consists of the corresponding expression level measured in a breast tumour sample selected from the group consisting of (i) a breast tumour sample from a patient who has not undergone cancer metastasis, and (ii) a breast tumour sample from a patient who has not undergone cancer metastasis in the lung.
 19. The method according to claim 17, wherein, at step b), the number of markers for which the expression level is determined is selected from the group consisting of 2, 3, 4, 5 and
 6. 20. The method according to claim 17, wherein step b) consists of determining the expression level of every one of the lung-specific markers comprised in the group of markers consisting of DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.
 21. The method according claim 17, wherein the markers are selected from the group consisting of mRNA, cDNA and protein.
 22. The method according to claim 17, wherein at step b), the said expression level of the one or more biological markers is determined by submitting the said breast tumour tissue sample to a gene expression analysis method.
 23. The method according to claim 17, wherein at step b), the expression level of said one or more biological markers is determined by submitting the said breast tumour tissue sample to a protein expression analysis method.
 24. The method according to claim 17, wherein step b) is performed by using a DNA microarray having probes specific for the one or more lung-specific markers immobilized thereon.
 25. The method according to claim 17, wherein, at step b), a nucleic acid amplification reaction is performed by using primers, or pairs of primers, specific for each of the one or more lung-specific markers whose expression is determined.
 26. The method according to claim 25, wherein the said pairs of primers are selected from the group consisting of SEQ ID No 59 and 60 (DSC2), SEQ ID No 51 and 52 (TFCP2L1), SEQ ID No 43 and 44 (UGT8), SEQ ID No 37 and 38 (ITGB8), SEQ ID No 33 and 34 (ANP32E) and the probe set referred to as “60474 at” in Table 5 (FERMT1).
 27. The method according to claim 17, wherein at step b), the expression level of said one or more biological markers is determined by submitting the said breast tumour tissue sample to an immunohistochemical analysis method.
 28. The method according to claim 17, wherein the expression of more than one lung-specific marker is determined at step b) and wherein step b) comprises the generation of an experimental expression profile of the said markers.
 29. The method according to claim 28, wherein, at step c), the experimental expression profile that is obtained at step b) is compared to a control expression profile of the same lung-specific markers.
 30. A kit for the in vitro prediction of the occurrence of lung metastasis in a breast cancer patient, which kit comprises means for determining the expression level of one or more biological markers selected from the group consisting of DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.
 31. A kit for monitoring the anti-metastasis effectiveness of a therapeutic treatment of a patient affected with a breast cancer with a pharmaceutical agent, which kit comprises means for determining the expression level of one or more biological markers selected from the group consisting of DSC2, TFCP2L1, UGT8, ITGB8, ANP32E and FERMT1.
 32. A kit according to claim 30, wherein the number of markers is selected from group consisting of 2, 3, 4, 5 and
 6. 33. A kit according to claim 30, comprising one or a combination or set of pair of primers, wherein each primer hybridizes specifically with one of the said one or more biological markers.
 34. A kit according to claim 30, comprising a DNA microarray comprising probes hybridizing to the nucleic acid expression products of the said one or more biological markers.
 35. A kit according to claim 30, comprising a combination or a set of antibodies, wherein each antibody is directed against one of the said one or more biological markers. 